Your search keyword '"Kaşkaş A"' showing total 182 results

51. An Application of Transport Theory in Optical Oceanography: The Estimation of the Apparent Optical Properties Using Henyey-Greenstein Phase Function

Author

Cevdet Tezcan and A. Kaşkaş

Subjects

Physics, Scattering, Applied Mathematics, Scalar (mathematics), General Physics and Astronomy, Dirac delta function, Transportation, Statistical and Nonlinear Physics, Transport theory, Inverse problem, symbols.namesake, Oceanography, Isotropic scattering, symbols, Phase function, Computer Science::Databases, Mathematical Physics

Abstract

Transport theory methods can be applied to optical oceanography to solve forward and inverse problems. The combination of delta function representing forward and backward scattering with isotropic scattering is used to obtain scalar and plane irradiances for Henyey-Greenstein phase function. Once the irradiances are obtained, the apparent optical properties can be found analytically and numerically.

Published

2009

52. Legendre polynomial series of the infinite medium Green's Function in neutral particle transport theory: the half-space albedo problem

Author

A. Kaşkaş and M. Ç. Güleçyüz

Subjects

Nuclear and High Energy Physics, Radiation, Series (mathematics), Mathematical analysis, Function (mathematics), Half-space, symbols.namesake, Associated Legendre polynomials, Nuclear Energy and Engineering, Green's function, symbols, General Materials Science, Safety, Risk, Reliability and Quality, Series expansion, Neutral particle, Legendre polynomials, Mathematics

Abstract

Series expansion of the infinite medium Green's function in terms of Legendre polynomials is used to solve the half-space albedo problem. The importance of this procedure is that it can be used for the solution of many different physical problems in plane geometry and can be extended to find the solution of the problems in other geometries.

Published

2009

53. Assessment of the Effect of Breathing Movements on the Skin Dose by Comparison of TLD Measurements and Plan Data in Breast Cancer Radiotherapy

Author

Ergün, D., primary, Aytaç Arslan, S., additional, and Kaşkaş, A., additional

Published

2018

54. Colaboradores

Author

Abbruzzese, James L., Abdel-Wahab, Omar, Abou-Alfa, Ghassan K., Abrahm, Janet L., Abrams, Jeffrey S., Abramson, Jeremy S., Aisner, Dara L., Alonso-Basanta, Michelle, Anampa, Jesus, Anderson, Megan E., Antonarakis, Emmanuel S., Aplenc, Richard, Appelbaum, Frederick R., Araujo, Luiz H., Asban, Ammar, Ashwood, Edward, Awan, Farrukh T., Aylward, Juliet L., Balar, Arjun V., Balentine, Courtney J., Barta, Stefan K., Bartlett, Nancy, Basen-Engquist, Karen, Beaupin, Lynda Kwon, Berkowitz, Ross S., Berry, Donald A., Bevers, Therese, Boggess, John F., Brahmer, Julie R., Brown, Janet, Brown, Karen, Brown, Powel, Browner, Ilene, Bunn, Paul A., Burns, William R., Byrd, John C., Cadoo, Karen, Carbone, David P., Carter, H. Ballentine, Castillo, Jorge J., Chang, Alfred E., Chang, Eric, Chanock, Stephen J., Chapuy, Claudia I., Chauhan, Vikash P., Chen, Herbert, Chen, Ronald C., Cheung, Nai-Kong V., Choe, Jennifer H., Christian, Michaele C., Cinciripini, Paul M., Clarke, Michael F., Coleman, Robert E., Coleman, Robert L., Coletta, Adriana M., Collins, Jerry M., Connors, Jean M., Cools, Michael, Coombes, Kevin R., Cortes, Jorge, Costa, Mauro W., Covey, Anne, Cowan, Kenneth H., Crane, Christopher H., Crawford, Jeffrey, Crooks, Kristy, Culkin, Daniel J., Czito, Brian G., Dalerba, Piero, Dalmau, Josep, Dang, Mai, D’Angelica, Michael, Davies, Kurtis D., Davis, Myrtle, Dea, Nicolas, De Jesus-Acosta, Ana, DeMarzo, Angelo M., DeWeese, Theodore L., Diehn, Maximilian, Digumarthy, Subba R., Dispenzieri, Angela, Do, Khanh T., Dobrenkov, Konstantin, Dome, Jeffrey S., Doroshow, James H., Dorsey, Jay F., Dubard-Gault, Marianne, DuBois, Steven G., Duda, Dan G., Dunlop, Malcolm, Duska, Linda R., Duvic, Madeleine, Dika, Imane El, El-Serag, Hashem, Engelmann, Jeffrey M., Ettinger, David S., Fashoyin-Aje, Lola A., Fearon, Eric R., Ford, James M., Franklin, Wilbur A., Freer, Phoebe E., Freidlin, Boris, Freifeld, Alison G., Friedlander, Terence W., Friedman, Debra L., Fuller, Arian F., Galluzzi, Lorenzo, Gebhardt, Mark C., George, Daniel J., Geyer, Mark B., Giaccia, Amato J., Gilbert, Mark R., Goldner, Whitney, Goldstein, Donald P., Goodman, Annekathryn, Goodman, Karyn A., Gordon, Kathleen, Graeff-Armas, Laura, Greenstein, Alexander J., Grossman, Stuart A., Grupp, Stephan, Gupta, Arjun, Haider, Irfanullah, Haigentz, Missak, Hainsworth, John D., Haithcock, Benjamin E., Hallemeier, Christopher L., Hanash, Samir, Hanrahan, Aphrothiti J., Harding, James, Harrison, Michael R., Hasham, Muneer G., Hawk, Ernest, Hayman, Jonathan, Heinlen, Jonathan E., Henry, N. Lynn, Herman, Joseph, Hobbs, Brian P., Holen, Ingunn, Horn, Leora, Horowitz, Neil S., Horwitz, Steven M., Houghton, Odette, Howard, Scott C., Hudis, Clifford A., Hunger, Stephen P., Hurria, Arti, Ilson, David H., Im, Annie, Iyer, Gopa, Jaffee, Elizabeth M., Jagsi, Reshma, Jain, Rakesh K., Jarnagin, William, Jatoi, Aminah, Jhingran, Anuja, Johnson, David H., Johnston, Brian, Johnston, Patrick G., Judy, Kevin D., Kachnic, Lisa A., Kaidar-Person, Orit, Kalva, Sanjeeva, Kamin, Deborah Y., Kantarjian, Hagop, Karakousis, Giorgos, Karam-Hage, Maher, Kaskas, Nadine M., Kastan, Michael B., Katabi, Nora, Kaul, Daniel R., Kelley, Scott R., Kemeny, Nancy, Kent, Erin E., Kepp, Oliver, Khagi, Simon, Kilgore, Joshua E., Kim, D. Nathan, Kleinschmidt-DeMasters, Bette K., Korn, Edward L., Kroemer, Guido, Ku, Geoffrey Y., Kummar, Shivaani, Ky, Bonnie, Laheru, Daniel A., Lambert, Paul F., Lawler, Mark, Le-Rademacher, Jennifer G., Lee, John Y.K., Lee, Nancy Y., Lee, Susanna L., Leeman, Jonathan E., Linkermann, Andreas, Liu, Jinsong, Lo, Simon, Locasale, Jason W., Loprinzi, Charles L., Lowery, Maeve, Ludwig, Emmy, Lunning, Matthew A., Lustig, Robert A., Machtay, Mitchell, Mackall, Crystal, Mahvi, David A., Mahvi, David M., Maity, Amit, Majithia, Neil, Malumbres, Marcos, Maresso, Karen Colbert, Martin, John D., Matsuo, Koji, Matthews, Natalie H., Mauro, Lauren, Mayer, R. Samuel, McCaskill-Stevens, Worta, McNamara, Megan A., Mehta-Shah, Neha, Merritt, Robert E., Milowsky, Matthew I., Minasian, Lori M., Mitchell, Tara C., Mitsis, Demytra, Mollica, Michelle, Mooney, Margaret, Moustafa, Farah, Nabati, Lida, Naidoo, Jarushka, Narang, Amol, Nelson, Heidi, Nelson, William G., Nesbit, Suzanne, Niglas, Mark, O’Connor, Tracey, Offit, Kenneth, Onciu, Mihaela, O’Reilly, Eileen M., Ostrander, Elaine A., Pappas-Taffer, Lisa, Pardoll, Drew, Park, Jae H., Patel, Anery, Patel, Anish J., Patierno, Steven R., Pavletic, Steven Z., Phillips, Peter C., Post, Miriam D., Pruitt, Amy A., Querfeld, Christiane, Rabius, Vance A., Rajkumar, S. Vincent, Ramadan, Mohammad O., Rankin, Erinn B., Reddy, Sushanth, Reid, Michael A., Reznik, Scott, Rizack, Tina, Robinson, Jason D., Robinson-Bostom, Leslie, Rodriguez-Galindo, Carlos, Romesser, Paul B., Rosen, Steven T., Rosenfeld, Myrna R., Rosenthal, Nadia, Ross, Meredith, Rowland, Julia H., Russell, Anthony H., Sabel, Michael S., Sahgal, Arjun, Salinas, Ryan D., Salo-Mullen, Erin E., Salto-Tellez, Manuel, Sanderson, Sydney M., Sandlund, John T., Santana, Victor M., Savage, Michelle, Schreiber, Eric C., Schuchter, Lynn, Schultz, Liora, Seiden, Michael V., Sellers, Morgan M., Shah, Payal D., Shia, Jinru, Shilo, Konstantin, Small, Eric, Smith, Angela B., Snow, Stephen N., Solit, David B., Sood, Anil K., Soto-Perez-de-Celis, Enrique, Sparano, Joseph A., Spiegelman, Vladimir S., Spunt, Sheri L., Stadler, Zsofia K., Steensma, David P., Stone, Richard M., Stranne, Steven Kent, Stratton, Kelly, Sugden, Bill, Swanson, Andrew M., Tallman, Martin S., Talmadge, James E., Teachey, David T., Teba, Catalina V., Tefferi, Ayalew, Teh, Bin Tean, Teng, Joyce M.C., Tepper, Joel E., Thaker, Premal H., Thrift, Aaron P., Tran, Arthur-Quan, Triska, Grace, Trump, Donald, Tsai, Kenneth, Tseng, Chia-Lin, Tseng, Diane, Van Schaeybroeck, Sandra, Van Tine, Brian A., Vanness, Erin R., Varadhachary, Gauri, Varella-Garcia, Marileila, Wahl, Richard L., Walsh, Michael F., Wang, Thomas, Weiss, Jared, Weissman, Irving L., Westin, Shannon N., White, Jeffrey D., Wilson, Richard, Wong, Richard J., Wood, Gary S., Xu, Yaohui G., Xu-Welliver, Meng, Yust-Katz, Shlomit, Zagar, Timothy, Zeman, Elaine M., Zhang, Tian, and Zwiebel, James A.

Published

2020

55. 41 - Efectos tóxicos dermatológicos del tratamiento contra el cáncer

Author

Matthews, Natalie H., Moustafa, Farah, Kaskas, Nadine M., Robinson-Bostom, Leslie, and Pappas-Taffer, Lisa

Published

2020

56. Conceptual design of the early implementation of the NEutron Detector Array (NEDA) with AGATA

Author

Victor Modamio, P. A. Söderström, Ramon Jose Aliaga-Varea, C. Domingo-Pardo, Enrique Sanchis, Nizamettin Erduran, A. Triossi, Jose Javier Valiente-Dobón, Giacomo de Angelis, R. Wadsworth, Vicente González, R. Gadea, Grzegorz Jaworski, Antonio Di Nitto, S. Erturk, Marek Moszynski, V. Herrero-Bosch, M. Palacz, Johan Nyberg, F.J. Egea, A. Kaşkaş, A. Atac, J. Collado, A. Gadea, T. Hüyük, Huyuk, T., Di Nitto, A., Jaworski, G., Gadea, A., Javier Valiente-Dobon, J., Nyberg, J., Palacz, M., Soderstrom, P. -A., Jose Aliaga-Varea, R., de Angelis, G., Atac, A., Collado, J., Domingo-Pardo, C., Egea, F. J., Erduran, N., Erturk, S., de France, G., Gadea, R., Gonzalez, V., Herrero-Bosch, V., Kaskas, A., Modamio, V., Moszynski, M., Sanchis, E., Triossi, A., Wadsworth, R., Grand Accélérateur National d'Ions Lourds (GANIL), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), AGATA, Huyuk, Tayfun -- 0000-0003-0597-9767, Triossi, Andrea -- 0000-0001-5140-9154, Millan, Vicente Gonzalez -- 0000-0001-6014-2586, Di Nitto, Antonio -- 0000-0002-9319-366X, SANCHIS, ENRIQUE -- 0000-0002-9689-9131, Domingo-Pardo, Cesar -- 0000-0002-2915-5466, Herrero-Bosch, Vicente -- 0000-0003-0860-2789, Gadea, Andres -- 0000-0002-4233-1970, Aliaga, Ramon J. -- 0000-0002-2513-7711, Jaworski, Grzegorz -- 0000-0003-2241-0329, Gadea-Girones, Rafael -- 0000-0003-2857-8667, de France, Gilles -- 0000-0002-7439-1759, Soderstrom, Par-Anders -- 0000-0002-9504-2814, [Hueyuek, Tayfun -- Gadea, Andres -- Jose Aliaga-Varea, Ramon -- Domingo-Pardo, Cesar] Univ Valencia, CSIC, Inst Fis Corpuscular, E-46980 Paterna, Valencia, Spain -- [Di Nitto, Antonio] Ist Nazl Fis Nucl, Sez Napoli, I-80126 Naples, Italy -- [Di Nitto, Antonio -- Ertuerk, Sefa] Johannes Gutenberg Univ Mainz, D-55099 Mainz, Germany -- [Jaworski, Grzegorz -- Valiente-Dobon, Jose Javier -- de Angelis, Giacomo -- Modamio, Victor -- Triossi, Andrea] Ist Nazl Fis Nucl, Lab Nazionali Legnaro, I-35020 Legnaro, PD, Italy -- [Palacz, Marcin] Univ Warsaw, Heavy Ion Lab, PL-02093 Warsaw, Poland -- [Nyberg, Johan] Uppsala Univ, Dept Phys & Astron, SE-75120 Uppsala, Sweden -- [Soederstroem, Paer-Anders] RIKEN, Nishina Ctr, Saitama 3510198, Japan -- [Jose Aliaga-Varea, Ramon -- Herrero-Bosch, Vicente] Univ Politecn Valencia, I3M, E-46022 Valencia, Spain -- [Atac, Ayse -- Kaskas, Ayse] Ankara Univ, Fac Sci, Dept Phys, TR-06100 Ankara, Turkey -- [Atac, Ayse] Royal Inst Technol, SE-10691 Stockholm, Sweden -- [Collado, Javier -- Egea, Francisco Javier -- Gonzalez, Vicente -- Sanchis, Enrique] Univ Valencia, Dept Elect Engn, Burjassot 34303, Valencia, Spain -- [Erduran, Nizamettin] Istanbul Sabahattin Zaim Univ, Fac Engn & Nat Sci, TR-34303 Istanbul, Turkey -- [Ertuerk, Sefa] Nigde Univ, Fac Sci & Arts, Dept Phys, TR-51240 Nigde, Turkey -- [de France, Gilles] CEA, DSAM, GANIL, F-14076 Caen, France -- [de France, Gilles] CNRS, IN2P3, F-14076 Caen, France -- [Moszynski, Marek] Natl Ctr Nucl Res, PL-05400 Otwock, Poland -- [Wadsworth, Robert] Univ York, Dept Phys, York YO10 5DD, N Yorkshire, England, and 0-Belirlenecek

Subjects

Physics, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 7. Clean energy, 01 natural sciences, 0-Belirlenecek, TECNOLOGIA ELECTRONICA, Nuclear physics, Conceptual design, 0103 physical sciences, Nuclear fusion, Neutron detection, High Energy Physics::Experiment, AGATA, Nuclear Experiment, 010306 general physics, ComputingMilieux_MISCELLANEOUS

Abstract

WOS: 000372866900001, The NEutron Detector Array (NEDA) project aims at the construction of a new high-efficiency compact neutron detector array to be coupled with large gamma-ray arrays such as AGATA. The application of NEDA ranges from its use as selective neutron multiplicity filter for fusion-evaporation reaction to a large solid angle neutron tagging device. In the present work, possible configurations for the NEDA coupled with the Neutron Wall for the early implementation with AGATA has been simulated, using Monte Carlo techniques, in order to evaluate their performance figures. The goal of this early NEDA implementation is to improve, with respect to previous instruments, efficiency and capability to select multiplicity for fusion-evaporation reaction channels in which 1, 2 or 3 neutrons are emitted. Each NEDA detector unit has the shape of a regular hexagonal prism with a volume of about 3.23 l and it is filled with the EJ301 liquid scintillator, that presents good neutron-gamma discrimination properties. The simulations have been performed using a fusion-evaporation event generator that has been validated with a set of experimental data obtained in the Ni-58 + Fe-56 reaction measured with the Neutron Wall detector array., MINECO, Spain [FPA2011-29854-C04, FPA2012-33650, FPA2014-57196-C5]; Generalitat Valenciana, Spain [PROMETEO/2010/101, PROMETEOII/2014/019]; European Regional Development Fund (FEDER) of European Commission; Swedish Research Council; Polish National Science Centre [801/N-COPIN/2010/0, UM0-2014/14/M/ST2/00738, UM0-2013/08/M/ST2/0025]; Scientific and Technological Council of Turkey [106T055, 114F473]; UK STFC [ST/L005727/1]; Science and Technology Facilities Council [ST/L005727/1, ST/L005735/1], This work was partially supported by MINECO, Spain, under the grants FPA2011-29854-C04, FPA2012-33650 and FPA2014-57196-C5, and Generalitat Valenciana, Spain, under the grants PROMETEO/2010/101 and PROMETEOII/2014/019, The European Regional Development Fund (FEDER) of European Commission, the Swedish Research Council, the Polish National Science Centre under contracts: 801/N-COPIN/2010/0 (COPIN/IN2P3 collaboration), UM0-2014/14/M/ST2/00738 (COPIN-INFN collaboration), UM0-2013/08/M/ST2/0025 (LEA-COPIGAL collaboration), the Scientific and Technological Council of Turkey (Proj. no. 106T055 and 114F473), and the UK STFC (ST/L005727/1).

Published

2016

57. The effects of different expansions of the exit distribution on the extrapolation length for linearly anisotropic scattering

Author

M. Ç. Güleçyüz, S. Bulut, A. Kaşkaş, and Cevdet Tezcan

Subjects

Physics, Nuclear and High Energy Physics, Radiation, Mathematical analysis, Zero (complex analysis), Extrapolation, Eigenfunction, Half-space, Distribution (mathematics), Nuclear Energy and Engineering, Orthogonality, General Materials Science, Safety, Risk, Reliability and Quality, Convection–diffusion equation, Legendre polynomials

Abstract

HN and singular eigenfunction methods are used to determine the neutron distribution everywhere in a source-free half space with zero incident flux for a linearly anisotropic scattering kernel. The singular eigenfunction expansion of the method of elementary solutions is used. The orthogonality relations of the discrete and continuous eigenfunctions for linearly anisotropic scattering provides the determination of the expansion coefficients. Different expansions of the exit distribution are used: the expansion in powers of μ, the expansion in terms of Legendre polynomials and the expansion in powers of 1/(1 + μ). The results are compared to each other. In the second part of our work, the transport equation and the infinite medium Green function are used. The numerical results of the extrapolation length obtained for the different expansions is discussed.

Published

2007

58. Neutron transport problems for extremely anisotropic scattering

Author

A. Kaşkaş, M. Ç. Güleçyüz, and M. Karahasanoğlu

Subjects

Physics, Nuclear and High Energy Physics, Neutron transport, Radiation, Analytical expressions, business.industry, Numerical analysis, Albedo, Half-space, Computational physics, Anisotropic scattering, Optics, Nuclear Energy and Engineering, Slab, General Materials Science, Safety, Risk, Reliability and Quality, business

Abstract

Half-space albedo, slab albedo and critical slab problems will be solved for extremely anisotropic scattering using the analytical expressions of the FN method with a different numerical approximation. The infinite medium Green's function for the anisotropic scattering case obtained in terms of the infinite medium Green's function for the isotropic scattering is used. The numerical results are compared with data available in the literature.

Published

2006

59. AGATA-Advanced GAmma Tracking Array

Author

A. Colombo, Y. Mariette, A. Johnson, W. Korten, A. Brondi, T. Faul, J. Robin, R. Depalo, M. Slee, J. Gre¸bosz, H. C. Boston, H. Harroch, B. Rossé, M. Filliger, M. Gulmini, A. Korichi, S. Brambilla, J.R. Cresswell, C. Parisel, P. Edelbruck, F. Ameil, F. Camera, C. Oziol, Matthew Richard Dimmock, G. Salvato, F. Morbiducci, J. Ropert, M. Borsato, E. Legay, Marco Bellato, C. Santos, Gheorghe Pascovici, L. Charles, J. Pancin, G. Casati, P. G. Bizzeti, T. Stanios, S. Lhenoret, Diego Barrientos, P.M. Jones, Andreas Görgen, V. Chambert, S. Aydin, K. Hauschild, B. Hervieu, R. Nicolini, J. Simpson, H. J. Wollersheim, L. Lavergne, Pär-Anders Söderström, G. S. Simpson, G. Jaworski, F. Filmer, R. Griffiths, P.S. Morrall, M. Petcu, G. Lo Bianco, D. Linget, A. Givechev, D. C. Oxley, M. Kogimtzis, F. Salomon, J. Jolie, D. Wells, S. Moon, C. Aufranc, A. Corsi, T. Descombes, N. Goel, J. Thornhill, N. Warr, Serkan Akkoyun, B. Birkenbach, F. Dorangeville, Joël Chavas, P. Medina, Roberto Isocrate, C. Weber, E. Merchan, Bo Cederwall, I. Kojouharov, Enrique Sanchis, A. Lopez-Martens, Oliver Wieland, F. Le Blanc, D. Seddon, S. C. Letts, D. Bazzacco, J. Leske, B. Bruyneel, Alberto Pullia, L. Nelson, G. La Rana, B. Travers, I. Burrows, G. Maron, S. Coelli, J. J. Valiente-Dobón, F. Saillant, Piotr Bednarczyk, V.L. Ngo, J. Mierzejewski, Norbert Pietralla, R.S. Kempley, N. Kurz, M. Rebeschini, S. Fantinel, D. L. Balabanski, A. J. Boston, F. Tomasi, R. Berthier, M. D. Salsac, B. Dulny, C. Stahl, N. Dosme, C. Fanin, R. Baumann, S. Pietri, A. Astier, M. Nicoletto, J. van der Marel, A. Bracco, Björn Jonson, D. Mengoni, D. Bloor, Luna Pellegri, F. Lefebvre, D. Pugnére, J. Egea, S. Cabaret, D. Curien, M. Reese, C. Commeaux, Dirk Rudolph, A. Giannatiempo, F. Recchia, L. Ramina, A. Lermitage, C. A. Ur, R. M. Lieder, I.P. Brawn, R. Menegazzo, R. Raine, Krasimir Mitev, D. R. Napoli, G. Suliman, M. Kebbiri, Y. Drouen, Susan Rigby, W. Me¸czyński, R. Wadsworth, F. Didierjean, P. Desesquelles, Ch. Veyssiere, S. Leoni, Vicente González, P. Gros, Y. Le Noa, M. Castoldi, O. Möller, R. Orlandi, Thomas Beck, M. Şenyiğit, A. Jungclaus, L. Gibelin, Mohammed Kaci, Zs. Podolyák, J. Gerl, S. Erturk, W. Gast, B. Melon, V. Mendéz, R. Peghin, P. Molini, M. N. Erduran, D. Conventi, Pankaj S. Joshi, E. Clément, F.A. Beck, A. Austin, A. Cortesi, J. Palin, P. Cocconi, L. J. Harkness, F. C. L. Crespi, Dirk Weisshaar, P. Sona, A. Czermak, D. Lersch, N. Blasi, Anton Khaplanov, O. Stezowski, B. Rubio, R. Venturelli, M.-H. Sigward, E. Viscione, José Salt, C. S. Özben, Giancarlo Ripamonti, P. Spolaore, Johan Nyberg, S. M. Lenzi, L. Legeard, N. Redon, C. Rossi Alvarez, C. He, R. Chapman, P. Le Pouhalec, C. Diarra, Herbert Hess, T. Engert, A. Kaşkaş, Stanislav Tashenov, S. Klupp, C. Michelagnoli, Elif Ince, A. Algora, J. F. Smith, M. Ozille, Alessandro Zucchiatti, Angelo Geraci, A. Olariu, M. Labiche, N. Karkour, Stefano Riboldi, P. Bourgault, C. M. Petrache, M. Palacz, M. El Chambit, J.-L. Cercus, M. Zie¸bliński, Alex Wiens, R. Beunard, X. Lafay, T. Habermann, M. Karolak, L. Costa, Y. Aubert, Begoña Quintana, A P Robinson, V. F. E. Pucknell, D. Rosso, A. Capsoni, Emanuele Vardaci, L. Mihailescu, M. Tripon, E. Farnea, Ch. Theisen, Enrico Calore, G. Duchêne, N. V. Zamfir, X. Grave, S. Lunardi, I.H. Lazarus, José Blasco, D. Montanari, J.A. Sampson, P. H. Regan, N. Marginean, M. Pignanelli, L. Arnold, G. Benzoni, R. Krücken, G. de Angelis, D.P. Scraggs, I. Piqueras, D. M. Cullen, A. Obertelli, A. Bürger, D. Bortolato, G. Rainovski, A.R. Mather, P. Reiter, C. Unsworth, G. Baulieu, P. J. Coleman-Smith, C. Boiano, M. Richer, Sébastien Perrier, Agnese Giaz, Reynold J. Cooper, V. Vandone, S. Tanguy, C. Domingo-Pardo, A. Bouty, A. N. Grint, A. Maj, A. Gottardo, L. Berti, E. Pachoud, R. Marginean, E. A. Stefanova, A. Triossi, M. Nespolo, D. Bucurescu, R. Moro, H.T.M. Ha, D. S. Judson, J. L. Tain, A. Perego, Francesco Lelli, P. Detistov, B.Y. Ky, J. Ljungvall, B. Sowicki, M. Schlarb, F. Azaiez, P. Pariset, Ertan Şahin, R. Gernhäuser, M. Turcato, John Paul Strachan, B. Million, A. Atac, F. Carrio, D. Delbourg, F. Veronese, Th. Kröll, B. Cahan, A. Hernandez-Prieto, M. A. Bentley, K.M.M. Tun-Lanoë, B. Alikhani, P. Boutachkov, S. Leboutelier, Maria Doncel, A. M. Bizzeti-Sona, R. Touzery, A. Nannini, A. Lotode, P. J. Nolan, G. Rampazzo, F. Zocca, H. Schaffner, J. Eberth, A. Gadea, N. Toniolo, T. Hüyük, Q.T. Doan, P. Petkov, S. Broussard, S. Badoer, M. Rigato, Philip M Walker, J. Pouthas, Ch. Finck, L. Milechina, M. Norman, E. Pierre, J. Roccaz, S.J. Colosimo, Lázaro Guevara, Glyn Wittwer, Millan, Vicente Gonzalez -- 0000-0001-6014-2586, Rainovski, Georgi -- 0000-0002-1729-0249, Jaworski, Grzegorz -- 0000-0003-2241-0329, KORTEN, Wolfram -- 0000-0002-3940-0816, Domingo-Pardo, Cesar -- 0000-0002-2915-5466, Triossi, Andrea -- 0000-0001-5140-9154, Huyuk, Tayfun -- 0000-0003-0597-9767, Ince, Elif -- 0000-0003-4821-5441, Algora, Alejandro -- 0000-0002-5199-1794, Calore, Enrico -- 0000-0002-2301-3838, Rubio, Berta -- 0000-0002-9149-4151, THEISEN, Christophe -- 0000-0002-8509-1022, Rudolph, Dirk -- 0000-0003-1199-3055, Gadea, Andres -- 0000-0002-4233-1970, santos, cayetano -- 0000-0003-0727-1914, nannini, adriana -- 0000-0003-0659-7648, Depalo, Rosanna -- 0000-0003-3943-7982, Suliman, gabriel -- 0000-0001-8475-1992, Blasco, Jose-Maria -- 0000-0002-7663-9092, Petrache, Costel -- 0000-0001-8419-1390, Pietralla, Norbert -- 0000-0002-4797-3032, Cederwall, Bo -- 0000-0003-1771-2656, Zucchiatti, Alessandro -- 0000-0002-3647-596X, Mendez Munoz, Victor -- 0000-0002-9044-1189, Kruecken, Reiner -- 0000-0002-2755-8042, Napoli, Daniel Ricardo -- 0000-0002-8154-6958, Tain, Jose L. -- 0000-0002-3263-6965, SANCHIS, ENRIQUE -- 0000-0002-9689-9131, Zieblinski, Miroslaw -- 0000-0002-8693-7317, Hauschild, Karl -- 0000-0003-2862-2445, Montanari, Daniele -- 0000-0002-1980-7686, senyigit, menekse -- 0000-0002-2408-4419, La Rana, Giovanni -- 0000-0003-2814-4113, Menegazzo, Roberto -- 0000-0002-3060-5276, Soderstrom, Par-Anders -- 0000-0002-9504-2814, Unsworth, Carl -- 0000-0002-4100-7466, Camera, Franco -- 0000-0003-1731-4834, Gorgen, Andreas -- 0000-0003-1916-9941, Hernandez Prieto, Alvaro -- 0000-0002-0340-0240, Recchia, Francesco -- 0000-0002-8428-0112, de France, Gilles -- 0000-0002-7439-1759, GOTTARDO, Andrea -- 0000-0002-0390-5767, Perrier, Sebastien -- 0000-0001-5055-9046, Sowicki, Bogdan -- 0000-0002-7208-0690, Robinson, Andrew -- 0000-0002-2510-1321, Sahin, Eda -- 0000-0003-0683-5140, Pullia, Alberto -- 0000-0002-6393-747X, Lelli, Francesco -- 0000-0003-1900-9171, Clement, Emmanuel -- 0000-0003-1887-717X, benzoni, giovanna -- 0000-0002-7938-0338, Jonson, Bjorn -- 0000-0002-9697-9115, Bednarczyk, Piotr -- 0000-0002-5699-5292, Jones, Pete -- 0000-0001-7480-6603, Nicoletto, Marino -- 0000-0001-9301-0782, Ripamonti, Giancarlo -- 0000-0002-9406-021X, Bentley, Michael -- 0000-0001-8401-3455, Pellegri, Luna -- 0000-0002-3227-3332, Barrientos, Diego -- 0000-0001-9693-2942, GIAZ, Agnese -- 0000-0002-2550-450X, [Boston, A. J. -- Boston, H. C. -- Colosimo, S. -- Cooper, R. J. -- Cresswell, J. R. -- Dimmock, M. R. -- Filmer, F. -- Grint, A. N. -- Harkness, L. J. -- Judson, D. S. -- Mather, A. R. -- Moon, S. -- Nelson, L. -- Nolan, P. J. -- Norman, M. -- Oxley, D. C. -- Rigby, S. -- Sampson, J. -- Scraggs, D. P. -- Seddon, D. -- Slee, M. -- Stanios, T. -- Thornhill, J. -- Unsworth, C. -- Wells, D.] Univ Liverpool, Oliver Lodge Lab, Liverpool L69 7ZE, Merseyside, England -- [Akkoyun, S. -- Atac, A. -- Kaskas, A. -- Senyigit, M.] Ankara Univ, Fac Sci, Dept Phys, TR-06100 Ankara, Turkey -- [Algora, A. -- Barrientos, D. -- Domingo-Pardo, C. -- Egea, J. -- Gadea, A. -- Hueyuek, T. -- Kaci, M. -- Mendez, V. -- Rubio, B. -- Salt, J. -- Tain, J. L.] Univ Valencia, CSIC, IFIC, E-46980 Paterna, Spain -- [Alikhani, B. -- Boutachkov, P. -- Givechev, A. -- Goel, N. -- Leske, J. -- Merchan, E. -- Moeller, O. -- Pietralla, N. -- Reese, M. -- Stahl, C.] Tech Univ Darmstadt, IKP, D-64289 Darmstadt, Germany -- [Ameil, F. -- Beck, T. -- Boutachkov, P. -- Domingo-Pardo, C. -- Engert, T. -- Gerl, J. -- Goel, N. -- Habermann, T. -- Kojouharov, I. -- Kurz, N. -- Merchan, E. -- Pietri, S. -- Schaffner, H. -- Tashenov, S. -- Wollersheim, H. J.] GSI Helmholtzzentrum Schwerionenforsch GmbH, D-64291 Darmstadt, Germany -- [de Angelis, G. -- Badoer, S. -- Berti, L. -- Calore, E. -- Cocconi, P. -- Conventi, D. -- Costa, L. -- Fantinel, S. -- Gadea, A. -- Gottardo, A. -- Gulmini, M. -- He, C. -- Ince, E. -- Kroell, Th. -- Lelli, F. -- Maron, G. -- Molini, P. -- Napoli, D. R. -- Rigato, M. -- Rosso, D. -- Sahin, E. -- Spolaore, P. -- Toniolo, N. -- Valiente-Dobon, J. J.] Ist Nazl Fis Nucl, Lab Nazl Legnaro, IT-35020 Padua, Italy -- [Arnold, L. -- Baumann, R. -- Beck, F. A. -- El Chambit, M. -- Charles, L. -- Curien, D. -- Didierjean, F. -- Duchene, G. -- Faul, T. -- Filliger, M. -- Finck, Ch. -- Medina, P. -- Pachoud, E. -- Parisel, C. -- Piqueras, I. -- Richer, M. -- Robin, J. -- Santos, C. -- Sigward, M. -H. -- Weber, C.] Univ Strasbourg, IPHC, F-67037 Strasbourg, France -- [Arnold, L. -- Baumann, R. -- Beck, F. A. -- El Chambit, M. -- Charles, L. -- Curien, D. -- Didierjean, F. -- Duchene, G. -- Faul, T. -- Filliger, M. -- Finck, Ch. -- Medina, P. -- Pachoud, E. -- Parisel, C. -- Piqueras, I. -- Richer, M. -- Robin, J. -- Santos, C. -- Sigward, M. -H. -- Weber, C.] CNRS, UMR 7178, F-67037 Strasbourg, France -- [Astier, A. -- Cabaret, S. -- Desesquelles, P. -- Dosme, N. -- Gibelin, L. -- Ha, H. T. M. -- Hauschild, K. -- Karkour, N. -- Korichi, A. -- Lafay, X. -- Leboutelier, S. -- Legay, E. -- Lhenoret, S. -- Linget, D. -- Ljungvall, J. -- Lopez-Martens, A. -- Morbiducci, F. -- Ngo, V. L. -- Pariset, P. -- Perrier, S. -- Pierre, E. -- Roccaz, J. -- Travers, B.] Univ Paris 11, CNRS, IN2P3, CSNSM, F-91405 Orsay, France -- [Atac, A. -- Nyberg, J. -- Soderstrom, P. -A.] Uppsala Univ, Dept Phys & Astron, Uppsala, Sweden -- [Atac, A. -- Cederwall, B. -- Johnson, A. -- Khaplanov, A. -- van der Marel, J. -- Milechina, L. -- Tashenov, S.] Royal Inst Technol, SE-10691 Stockholm, Sweden -- [Aubert, Y. -- Azaiez, F. -- Le Blanc, F. -- Cercus, J. -L. -- Chambert, V. -- Commeaux, C. -- Delbourg, D. -- Diarra, C. -- Dorangeville, F. -- Edelbruck, P. -- Grave, X. -- Guevara, L. -- Harroch, H. -- Ky, B. Y. -- Lavergne, L. -- Lefebvre, F. -- Lermitage, A. -- Olariu, A. -- Oziol, C. -- Petrache, C. -- Pouthas, J. -- Salomon, F. -- Tanguy, S. -- Tun-Lanoe, K. M. M.] Univ Paris 11, CNRS, IN2P3, IPNO, F-91406 Orsay, France -- [Aufranc, C. -- Baulieu, G. -- Doan, Q. T. -- Pugnere, D. -- Redon, N. -- Rosse, B. -- Stezowski, O.] Univ Lyon 1, CNRS, IN2P3, Inst Phys Nucl Lyon, F-69622 Villeurbanne, France -- [Austin, A. -- Burrows, I. -- Coleman-Smith, P. J. -- Griffiths, R. -- Kogimtzis, M. -- Labiche, M. -- Lazarus, I. H. -- Letts, S. C. -- Morrall, P. S. -- Palin, J. -- Pucknell, V. F. E. -- Simpson, J. -- Strachan, J.] STFC Daresbury Lab, Warrington WA4 4AD, Cheshire, England -- [Aydin, S. -- Bazzacco, D. -- Bellato, M. -- Bortolato, D. -- Chavas, J. -- Colombo, A. -- Fanin, C. -- Farnea, E. -- Isocrate, R. -- Kroell, Th. -- Lenzi, S. M. -- Lunardi, S. -- Marginean, R. -- Menegazzo, R. -- Mengoni, D. -- Michelagnoli, C. -- Nespolo, M. -- Nicoletto, M. -- Peghin, R. -- Ramina, L. -- Rampazzo, G. -- Rebeschini, M. -- Recchia, F. -- Rossi Alvarez, C. -- Salvato, G. -- Triossi, A. -- Turcato, M. -- Ur, C. A. -- Venturelli, R. -- Veronese, F.] Ist Nazl Fis Nucl, Sez Padova, IT-35131 Padua, Italy -- [Balabanski, D. L. -- Detistov, P. -- Petkov, P. -- Stefanova, E.] Bulgarian Acad Sci, Inst Nucl Res & Nucl Energy, Sofia, Bulgaria -- [Bednarczyk, P. -- Czermak, A. -- Dulny, B. -- Grebosz, J. -- Maj, A. -- Meczynski, W. -- Sowicki, B. -- Zieblinski, M.] Polish Acad Sci, Henryk Niewodniczanski Inst Nucl Phys, PL-31342 Krakow, Poland -- [Bentley, M. A. -- Bloor, D. -- Joshi, P. -- Wadsworth, R.] Univ York, Dept Phys, York YO10 5DD, N Yorkshire, England -- [Benzoni, G. -- Blasi, N. -- Boiano, C. -- Bracco, A. -- Brambilla, S. -- Camera, F. -- Capsoni, A. -- Casati, G. -- Coelli, S. -- Corsi, A. -- Cortesi, A. -- Crespi, F. C. L. -- Geraci, A. -- Giaz, A. -- Leoni, S. -- Million, B. -- Montanari, D. -- Nicolini, R. -- Pellegri, L. -- Pignanelli, M. -- Pullia, A. -- Riboldi, S. -- Ripamonti, G. -- Tomasi, F. -- Vandone, V. -- Viscione, E. -- Wieland, O. -- Zocca, F.] Ist Nazl Fis Nucl, Sez Milano, IT-20133 Milan, Italy -- [Berthier, R. -- Bouty, A. -- Broussard, S. -- Buerger, A. -- Drouen, Y. -- Gros, P. -- Goergen, A. -- Hervieu, B. -- Karolak, M. -- Kebbiri, M. -- Korten, W. -- Ljungvall, J. -- Lotode, A. -- Mariette, Y. -- Le Noa, Y. -- Obertelli, A. -- Le Pouhalec, P. -- Salsac, M. -D. -- Theisen, Ch. -- Touzery, R. -- Veyssiere, Ch.] CEA, Ctr Saclay, IRFU, F-91191 Gif Sur Yvette, France -- [Beunard, R. -- Bourgault, P. -- Cahan, B. -- Clement, E. -- de France, G. -- Legeard, L. -- Ozille, M. -- Pancin, J. -- Raine, R. -- Ropert, J. -A. -- Saillant, F. -- Tripon, M. -- Wittwer, G.] CEA DSM CNRS IN2P3, GANIL, F-14076 Caen, France -- [Birkenbach, B. -- Bruyneel, B. -- Eberth, J. -- Hess, H. -- Jolie, J. -- Lersch, D. -- Pascovici, G. -- Reiter, P. -- Warr, N. -- Weisshaar, D. -- Wiens, A.] Univ Cologne, IKP, D-50937 Cologne, Germany -- [Bizzeti, P. G. -- Bizzeti-Sona, A. M. -- Giannatiempo, A. -- Melon, B. -- Perego, A. -- Sona, P.] Univ Florence, Dipartimento Fis & Astron, IT-50019 Florence, Italy -- [Bizzeti, P. G. -- Bizzeti-Sona, A. M. -- Giannatiempo, A. -- Melon, B. -- Nannini, A. -- Perego, A. -- Sona, P.] Ist Nazl Fis Nucl, Sez Firenze, IT-50019 Florence, Italy -- [Blasco, J. M. -- Carrio, F. -- Egea, J. -- Gonzalez, V. -- Sanchis, E.] Univ Valencia, Dept Elect Engn, E-46100 Burjassot, Valencia, Spain -- [Borsato, M. -- Bortolato, D. -- Lenzi, S. M. -- Lunardi, S. -- Marginean, R. -- Mengoni, D. -- Michelagnoli, C. -- Nespolo, M. -- Recchia, F. -- Salvato, G. -- Triossi, A. -- Venturelli, R.] Univ Padua, Dipartimento Fis, IT-35131 Padua, Italy -- [Bracco, A. -- Camera, F. -- Corsi, A. -- Crespi, F. C. L. -- Giaz, A. -- Leoni, S. -- Montanari, D. -- Nicolini, R. -- Pellegri, L. -- Pignanelli, M. -- Pullia, A. -- Riboldi, S. -- Vandone, V.] Univ Milan, Dipartimento Fis, IT-20133 Milan, Italy -- [Brawn, I. P.] STFC Rutherford Appleton Lab, Didcot OX11 0QX, Oxon, England -- [Brondi, A. -- Moro, R. -- La Rana, G. -- Vardaci, E.] Univ Naples Federico II, Dipartimento Fis, IT-80126 Naples, Italy -- [Brondi, A. -- Moro, R. -- La Rana, G. -- Vardaci, E.] Ist Nazl Fis Nucl, Sez Napoli, IT-80126 Naples, Italy -- [Bucurescu, D. -- Marginean, N. -- Marginean, R. -- Petcu, M. -- Ur, C. A.] Natl Inst Phys & Nucl Engn, Bucharest, Romania -- [Buerger, A. -- Suliman, G. -- Zamfir, N. V.] Univ Bonn, Helmholtz Inst Strahlen & Kernphys, D-53115 Bonn, Germany -- [Buerger, A.] Univ Oslo, Dept Phys, N-0316 Oslo, Norway -- [Casati, G. -- Geraci, A. -- Ripamonti, G.] Politecn Milan, Dipartimento Elettron & Informaz, IT-20133 Milan, Italy -- [Castoldi, M. -- Zucchiatti, A.] Ist Nazl Fis Nucl, Sez Genova, IT-16146 Genoa, Italy -- [Chapman, R. -- Mengoni, D. -- Orlandi, R. -- Smith, J. F.] Univ W Scotland, Sch Engn, Paisley PA1 2BE, Renfrew, Scotland -- [Cullen, D. M. -- Robinson, A. P.] Univ Manchester, Sch Phys & Astron, Schuster Lab, Manchester M13 9PL, Lancs, England -- [Depalo, R.] Univ Padua, Dipartimento Astron, IT-35131 Padua, Italy -- [Descombes, T. -- Simpson, G.] Univ Grenoble 1, CNRS, IN2P3, LPSC,INP Grenoble, F-38026 Grenoble, France -- [Doncel, M. -- Hernandez-Prieto, A. -- Quintana, B.] Univ Salamanca, Dept Fis Fundamental, E-37008 Salamanca, Spain -- [Erduran, M. N. -- Ince, E.] Istanbul Univ, Istanbul, Turkey -- [Erturk, S.] Nigde Univ, Fac Sci, Dept Phys, TR-51200 Nigde, Turkey -- [Gast, W. -- Lieder, R. M. -- Mihailescu, L.] Forschungszentrum Julich, Inst Kernphys, D-52425 Julich, Germany -- [Gernhaeuser, R. -- Klupp, S. -- Kruecken, R. -- Schlarb, M.] Tech Univ Munich, Phys Dept E12, D-85748 Garching, Germany -- [Jaworski, G.] Warsaw Univ Technol, Fac Phys, PL-00662 Warsaw, Poland -- [Jaworski, G. -- Mierzejewski, J. -- Palacz, M.] Univ Warsaw, Heavy Ion Lab, PL-02093 Warsaw, Poland -- [Jones, P.] Univ Jyvaskyla, Dept Phys, FI-40014 Jyvaskyla, Finland -- [Jonson, B.] Chalmers, S-41296 Gothenburg, Sweden -- [Jungclaus, A. -- Orlandi, R.] CSIC, Inst Estruct Mat, E-28006 Madrid, Spain -- [Kempley, R. S. -- Podolyak, Z. -- Regan, P. H. -- Walker, P. M.] Univ Surrey, Dept Phys, Guildford GU2 7XH, Surrey, England -- [Mitev, K. -- Rainovski, G.] Sofia Univ St Kliment Ohridski, Fac Phys, Sofia, Bulgaria -- [Ozben, C.] Istanbul Tech Univ, TR-80626 Istanbul, Turkey -- [Rudolph, D.] Lund Univ, Dept Phys, SE-22100 Lund, Sweden, Research Group: Information Management, CSNSM SNO, Centre de Spectrométrie Nucléaire et de Spectrométrie de Masse (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Institut de Physique Nucléaire d'Orsay (IPNO), informatique, Institut de Physique Nucléaire de Lyon (IPNL), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Institut Pluridisciplinaire Hubert Curien (IPHC), Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Grand Accélérateur National d'Ions Lourds (GANIL), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Département de Physique Nucléaire (ex SPhN) (DPHN), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, CSNSM MECA, Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Physique Subatomique et de Cosmologie (LPSC), Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS), CSNSM INFOR, CSNSM ELEC, Matière Nucléaire, Institut de Physique des 2 Infinis de Lyon (IP2I Lyon), AGATA, Akkoyun, S., Algora, A., Alikhani, B., Ameil, F., De Angelis, G, Arnold, L., Astier, A., Ataç, A., Aubert, Y., Aufranc, C., Austin, A., Aydin, S., Azaiez, F., Badoer, S., Balabanski, D. L., Barrientos, D., Baulieu G., L, Baumann, R., Bazzacco, D., Beck, F. A., Beck, T., Bednarczyk, P., Bellato, M., Bentley, M. A., Benzoni, G., Berthier, R., Berti, L., Beunard, R., Lo Bianco, G., Birkenbach, B., Bizzeti, P. G., Bizzeti Sona, A. M., Le Blanc, F., Blasco, J. M., Blasi, N., Bloor, D., Boiano, C., Borsato, M., Bortolato, D., Boston, A. J., Boston, H. C., Bourgault, P., Boutachkov, P., Bouty, A., Bracco, A., Brambilla, S., Brawn, I. P., Brondi, Augusto, Broussard, S., Bruyneel, B., Bucurescu, D., Burrows, I., Bürger, A., Cabaret, S., Cahan, B., Calore, E., Camera, F., Capsoni, A., Carrió, F., Casati, G., Castoldi, M., Cederwall, B., Cercus J., L, Chambert, V., El Chambit, M., Chapman, R., Charles, L., Chavas, J., Clément, E., Cocconi, P., Coelli, S., Coleman Smith, P. J., Colombo, A., Colosimo, S., Commeaux, C., Conventi, D., Cooper, R. J., Corsi, A., Cortesi, A., Costa, L., Crespi, F. C. L., Cresswell, J. R., Cullen, D. M., Curien, D., Czermak, A., Delbourg, D., Depalo, R., Descombes, T., Désesquelles, P., Detistov, P., Diarra, C., Didierjean, F., Dimmock, M. R., Doan, Q. T., Domingo Pardo, C., Doncel, M., Dorangeville, F., Dosme, N., Drouen, Y., Duchêne, G., Dulny, B., Eberth, J., Edelbruck, P., Egea, J., Engert, T., Erduran, M. N., Ertürk, S., Fanin, C., Fantinel, S., Farnea, E., Faul, T., Filliger, M., Filmer, F., Finck, C., De France, G., Gadea, A., Gast, W., Geraci, A., Gerl, J., Gernhäuser, R., Giannatiempo, A., Giaz, A., Gibelin, L., Givechev, A., Goel, N., González, V., Gottardo, A., Grave, X., Grȩbosz, J., Griffiths, R., Grint, A. N., Gros, P., Guevara, L., Gulmini, M., Görgen, A., Ha, H. T. M., Habermann, T., Harkness, L. J., Harroch, H., Hauschild, K., He, C., Hernández Prieto, A., Hervieu, B., Hess, H., Hüyük, T., Ince, E., Isocrate, R., Jaworski, G., Johnson, A., Jolie, J., Jones, P., Jonson, B., Joshi, P., Judson, D. S., Jungclaus, A., Kaci, M., Karkour, N., Karolak, M., Kaşkaş, A., Kebbiri, M., Kempley, R. S., Khaplanov, A., Klupp, S., Kogimtzis, M., Kojouharov, I., Korichi, A., Korten, W., Kröll, T., Krücken, R., Kurz, N., Ky, B. Y., Labiche, M., Lafay, X., Lavergne, L., Lazarus, I. H., Leboutelier, S., Lefebvre, F., Legay, E., Legeard, L., Lelli, F., Lenzi, S. M., Leoni, S., Lermitage, A., Lersch, D., Leske, J., Letts, S. C., Lhenoret, S., Lieder, R. M., Linget, D., Ljungvall, J., Lopez Martens, A., Lotodé, A., Lunardi, S., Maj, A., Van Der Marel, J., Mariette, Y., Marginean, N., Marginean, R., Maron, G., Mather, A. R., Mȩczyński, W., Mendéz, V., Medina, P., Melon, B., Menegazzo, R., Mengoni, D., Merchan, E., Mihailescu, L., Michelagnoli, C., Mierzejewski, J., Milechina, L., Million, B., Mitev, K., Molini, P., Montanari, D., Moon, S., Morbiducci, F., Moro, RENATA EMILIA MARIA, Morrall, P. S., Möller, O., Nannini, A, Napoli, D. R., Nelson, L., Nespolo, M., Ngo, V. L., Nicoletto, M., Nicolini, R., Le Noa, Y., Nolan, P. J., Norman, M., Nyberg, J., Obertelli, A., Olariu, A., Orlandi, R., Oxley, D. C., Özben, C., Ozille, M., Oziol, C., Pachoud, E., Palacz, M., Palin, J., Pancin, J., Parisel, C., Pariset, P., Pascovici, G., Peghin, R., Pellegri, L., Perego, A., Perrier, S., Petcu, M., Petkov, P., Petrache, C., Pierre, E., Pietralla, N., Pietri, S., Pignanelli, M., Piqueras, I., Podolyak, Z., Le Pouhalec, P., Pouthas, J., Pugnére D., L, Pucknell, V. F. E., Pullia, A., Quintana, B., Raine, R., Rainovski, G., Ramina, L., Rampazzo, G., LA RANA, Giovanni, Rebeschini, M., Recchia, F., Redon N., L, Reese M., C, Reiter, P., Regan, P. H., Riboldi, S., Richer, M., Rigato, M., Rigby, S., Ripamonti, G., Robinson, A., Robin, J., Roccaz, J., Ropert, J. A., Rossé, B. l., Rossi Alvarez, C., Rosso, D., Rubio, B., Rudolph, D., Saillant, F., Şahin, E., Salomon, F., Salsac, M. D., Salt, J., Salvato, G., Sampson, J., Sanchis, E., Santos, C., Schaffner, H., Schlarb, M., Scraggs, D. P., Seddon, D., Şenyiǧit, M., Sigward, M. H., Simpson, G., Simpson, J., Slee, M., Smith, J. F., Sona, P., Sowicki, B., Spolaore, P., Stahl, C., Stanios, T., Stefanova, E., Stézowski, O., Strachan, J., Suliman, G., Söderström, P. A., Tain, J. L., Tanguy, S., Tashenov, S., Theisen, C. h., Thornhill, J., Tomasi, F., Toniolo, N., Touzery, R., Travers, B., Triossi, A., Tripon, M., Tun Lanoë, K. M. M., Turcato, M., Unsworth, C., Ur, C. A., Valiente Dobon, J. J., Vandone, V., Vardaci, Emanuele, Venturelli, R., Veronese, F., Veyssiere, C., Viscione, E., Wadsworth, R., Walker, P. M., Warr, N., Weber, C., Weisshaar, D., Wells, D., Wieland, O., Wiens A., U, Wittwer, G., Wollersheim, H. J., Zocca, F., Zamfir, N. V., Ziȩbliński, M., Zucchiatti, A., Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3), Université de Strasbourg (UNISTRA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Joseph Fourier - Grenoble 1 (UJF)-Centre National de la Recherche Scientifique (CNRS), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), and 0-Belirlenecek

Subjects

Nuclear and High Energy Physics, Physics - Instrumentation and Detectors, Pulse-shape and gamma-ray tracking algorithms, FOS: Physical sciences, Semiconductor detector performance and simulations, Integrated circuit, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Tracking (particle physics), gamma-Ray tracking, 01 natural sciences, Pulse-shape and γ-ray tracking algorithms, law.invention, Data acquisition, law, 0103 physical sciences, ddc:530, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Nuclear Experiment (nucl-ex), 010306 general physics, γ-Ray spectroscopy, Nuclear Experiment, Instrumentation, Digital signal processing, Event reconstruction, gamma-Ray spectroscopy, Physics, sezele, Spectrometer, Spectrometers, 010308 nuclear & particles physics, business.industry, Detector, AGATA, Digital signals, HPGe detectors, Pulse-shape, Ray tracking, HPGe detectors, Algorithms, Crystals, Germanium, Semiconductor detectors, Signal processing, Spectrometry, Tracking (position), γ-Ray tracking, Instrumentation and Detectors (physics.ins-det), AGATA, Física nuclear, business, Computer hardware

Abstract

WOS: 000300864200005, The Advanced GAmma Tracking Array (AGATA) is a European project to develop and operate the next generation gamma-ray spectrometer. AGATA is based on the technique of gamma-ray energy tracking in electrically segmented high-purity germanium crystals. This technique requires the accurate determination of the energy, time and position of every interaction as a gamma ray deposits its energy within the detector volume. Reconstruction of the full interaction path results in a detector with very high efficiency and excellent spectral response. The realisation of gamma-ray tracking and AGATA is a result of many technical advances. These include the development of encapsulated highly segmented germanium detectors assembled in a triple cluster detector cryostat, an electronics system with fast digital sampling and a data acquisition system to process the data at a high rate. The full characterisation of the crystals was measured and compared with detector-response simulations. This enabled pulse-shape analysis algorithms, to extract energy, time and position, to be employed. In addition, tracking algorithms for event reconstruction were developed. The first phase of AGATA is now complete and operational in its first physics campaign. In the future AGATA will be moved between laboratories in Europe and operated in a series of campaigns to take advantage of the different beams and facilities available to maximise its science output. The paper reviews all the achievements made in the AGATA project including all the necessary infrastructure to operate and support the spectrometer. (C) 2011 Elsevier B.V. All rights reserved., EU [RII3-CT-2004-506065]; German BMBF [06K-167, 06KY2051]; Swedish Research Council; Knut and Alice Wallenberg Foundation; UK EPSRC Engineering and Physical Sciences Research Council; UK STFC Science and Technology Facilities Council; AWE plc; Scientific and Technological Research Council of Turkey [106T055]; Ankara University [05B4240002]; Polish Ministry of Science and Higher Education [DPN/N190/AGATA/2009]; Spanish MICINN [FPA2008-06419, FPA2009-13377-C02-02]; Spanish Consolider-Ingenio Programme CPAN [CSD2007-00042]; Generalitat Valenciana [PROMETEO/2010/101]; MICINN, Spain; INFN, Italy [AIC10-D-000568]; Science and Technology Facilities Council [ST/F012039/1, ST/J000094/1, ST/F004192/1, ST/J000159/1, ST/I504940/1, NuSTAR, ST/F006950/1, ST/I504916/1, ST/G000670/1, ST/F004060/1, ST/J000051/1, ST/J000108/1, ST/G000670/1 NuSTAR, ST/I504959/1, ST/G000727/1, ST/F004052/1, ST/F004184/1], AGATA and this work is supported by the European funding bodies and the EU Contract RII3-CT-2004-506065, the German BMBF under Grants 06K-167 and 06KY2051, the Swedish Research Council and the Knut and Alice Wallenberg Foundation, UK EPSRC Engineering and Physical Sciences Research Council, UK STFC Science and Technology Facilities Council, AWE plc, Scientific and Technological Research Council of Turkey (Proj. nr. 106T055) and Ankara University (BAP Proj. nr. 05B4240002), the Polish Ministry of Science and Higher Education under Grant DPN/N190/AGATA/2009, the Spanish MICINN under grants FPA2008-06419 and FPA2009-13377-C02-02, the Spanish Consolider-Ingenio 2010 Programme CPAN (contract number CSD2007-00042) the Generalitat Valenciana under Grant PROMETEO/2010/101, and research performed in the frame of the GSI-IN2P3 collaboration agreement number 02-42. A. Gadea and E. Farnea acknowledge the support of MICINN, Spain, and INFN, Italy, through the AIC10-D-000568 bilateral action.

Published

2012

60. Application of the HN method to the critical slab problem for reflecting boundary conditions

Author

R. G. Türeci, A. Kaşkaş, Cevdet Tezcan, M. Ç. Güleçyüz, and Kırıkkale Üniversitesi

Subjects

Radiation, Mathematical analysis, Physics::Optics, hybrid (H-N) method, Reflector (antenna), Atomic and Molecular Physics, and Optics, Slab, eigenvalues for the 20mfp slab thickness, Boundary value problem, Reflection coefficient, Special case, criticality problem, Spectroscopy, reflected boundary conditions

Abstract

Tureci, RG/0000-0001-6309-6300; gulecyuz, mustafa cetin/0000-0002-8838-7400 WOS: 000223457000006 The recently developed H-N method is used to solve the critical slab problem for a slab which is surrounded by a reflector. In the special case: for R = 0 (the reflection coefficient) the problem reduces to the one under vacuum boundary conditions. It is shown that the method is concise and leads to fast converging numerical results. The presented numerical results are compared with the data available in literature. (C) 2004 Elsevier Ltd. All rights reserved.

Published

2004

61. The HN method for solving linear transport equation: theory and applications

Author

Cevdet Tezcan, M. Ç. Güleçyüz, and A. Kaşkaş

Subjects

Lemma (mathematics), Radiation, Singular solution, Mathematical analysis, Slab, Neutron, Function (mathematics), Singular integral, Eigenfunction, Integral equation, Spectroscopy, Atomic and Molecular Physics, and Optics, Mathematics

Abstract

The system of singular integral equations which is obtained from the integro-differential form of the linear transport equation using the Placzek lemma is solved. The exit distributions at the boundaries of the various media and the infinite medium Green's function are used. The process is applied to the half-space and finite slab problems. The neutron angular density in terms of singular eigenfunctions of the method of elementary solutions is also used to derive the same analytical expressions.

Published

2003

62. Radiation transfer in an inhomogeneous half-space

Author

Cevdet Tezcan, A. Kaşkaş, and M. Ç. Güleçyüz

Subjects

Diffusion theory, Physics, Radiation, Radiation transfer, Homogeneous, Flux, Atomic physics, Half-space, Spectroscopy, Atomic and Molecular Physics, and Optics

Abstract

The emergent flux for radiation transfer in an inhomogeneous half-space for a new choice of c ( x ) c(x)=1− 1 (1+bx) 2 d− e (1+bx) 2 is calculated by using both the modified-Eddington method and the diffusion theory. Numerical results are given and in the special case as b →0 ( homogeneous media) they are compared with the previously reported values.

Published

2003

63. The Milne and the Constant Source Problems for the FBIS Kernel

Author

KAŞKAŞ, M.ç. Güleçyüz And A.

Subjects

Turk. J. Phys.,22,(1998),461-468. Full text: pdf Other articles published in the same issue: Turk. J. Phys.,vol.22,iss.6

Abstract

Transport solutions to the monoenergetic constant source and the Milne problems for the forward-backward-isotropic scattering (FBIS) kernel are obtained by method of singular expansion modes. The monoenergetic linear transport equation for extremely anisotropic scattering with constant source is reduced to a transport equation with isotropic scattering. The expansion coefficient is obtained in a form involving exact integral equations and determined by the accompanying new boundary conditions and the half-range orthogonality relations. In the zeroth order approximation, the analytical expressions for neutron density and the emergent angular distributions are also obtained as a function of forward scattering.

Published

2014

64. The singular eigenfunction analysis of the third form transport equation using half-range orthogonality relations: the half-space problems

Author

A. Kaşkaş, Cevdet Tezcan, and M. Ç. Güleçyüz

Subjects

Radiation, Mathematical analysis, Extrapolation, Fredholm integral equation, Eigenfunction, Half-space, Atomic and Molecular Physics, and Optics, symbols.namesake, Orthogonality, Singular solution, Simple (abstract algebra), symbols, Convection–diffusion equation, Spectroscopy, Mathematics

Abstract

The third form transport equation is solved using the infinite medium Green's functions in terms of the singular eigenfunctions of the method of elementary solutions and their half-range orthogonality relations. For simplicity, we consider only the Fredholm equation of the first kind and obtain the solution of the two problems for isotropic scattering: (i) the albedo problem for a source free half-space and (ii) the extrapolation length for the Milne problem. The convergence of the numerical results is fast as in C N method and the analytical expressions are simple for solving numerically.

Published

2001

65. The solution of the third form transport equation using singular eigenfunctions: the slab and the sphere criticality problems

Author

A. Kaşkaş, Cevdet Tezcan, and M. Ç. Güleçyüz

Subjects

Radiation, Criticality, Singular solution, Approximations of π, Mathematical analysis, Slab, Order (group theory), Function (mathematics), Eigenfunction, Convection–diffusion equation, Spectroscopy, Atomic and Molecular Physics, and Optics, Mathematics

Abstract

A singular eigenfunction approach is used to solve the classical slab and the sphere criticality problems. This approach is based on the use of the infinite medium Green's function which is obtained by the method of elementary solutions in the C N equations, that is in the third form of the transport equation. It is shown that our numerical results, even in the approximations of the lowest order are very accurate.

Published

2000

66. The singular eigenfunction method: the Milne problem for isotropic and extremely anisotropic scattering

Author

Cevdet Tezcan, A. Kaşkaş, and M.Ç. Güleşyüz

Subjects

Physics, Radiation, Isotropy, Mathematical analysis, Extrapolation, Eigenfunction, Atomic and Molecular Physics, and Optics, symbols.namesake, Fourier transform, Simple (abstract algebra), Quantum mechanics, symbols, Diffusion (business), Anisotropy, Convection–diffusion equation, Spectroscopy

Abstract

In the C N method of solving the third form of the transport equation, the medium as a result of Placzek lemma is extended to infinity. Infinite medium Green function which is obtained by the Fourier transform technique is used and the method is applied to one velocity problems in plane and cylindrical geometries. As the result of physical applications of the C N method in different geometries, it is seen that the only difficulty lies in writting the expression of the Green function in a form easy to handle. In the new method of solving the third form of the transport equation (that we have generated recently), three methods, namely, C N , F N and the method of elementary solutions are considered, compared and the Green function in terms of the singular eigenfunctions is used. This method yields simple analytical expressions that can be solved numerically more efficiently than the C N method because the expression of the Green function is in the form easy to handle. Here this new method is applied to calculate the extrapolation length for the Milne problem which is a classical problem in astrophysics concerned with the diffusion of radiation through a stellar atmosphere for both isotropic and anisotropic scatterings. It is shown that the numerical results which are tabulated for selected cases are accurate even in the approximations of the lowest order and are in good agreement with the numerical results obtained by the other methods.

Published

1999

67. SLAB ALBEDO PROBLEM FOR ANISOTROPIC SCATTERING USING SINGULAR EIGENFUNCTION SOLUTION OF THE CN EQUATIONS

Author

Cevdet Tezcan, A. Kaşkaş, and M. Ç. Güleçyüz

Subjects

Physics, Radiation, business.industry, Mathematical analysis, Eigenfunction, Albedo, Atomic and Molecular Physics, and Optics, Anisotropic scattering, Optics, Simple (abstract algebra), Convergence (routing), Slab, business, Convection–diffusion equation, Spectroscopy

Abstract

The albedo and the transmission factor for slabs for extremely anisotropic scattering are calculated. The solution of the problem is obtained using a new approach; that is the solution of the third form of the transport equation using the singular eigenfunctions of the method of elementary solutions. This approach leads simple equations for solving numerically when compared with C N method and also leads the convergence of the numerical results to be faster than that of the other methods in literature (i.e. F N -method).

Published

1999

68. 721 - Efficacy and Safety of Glecaprevir/Pibrentasvir in Renallyimpaired Patients with Chronic HCV Genotype 1-6 Infection

Author

Lawitz, Eric, Flisiak, Robert, Abunimeh, Manal, Sise, Meghan, Park, Jun Yong, Kaskas, Marwan, Bruchfeld, Annette, Wörns, Marcus-Alexander, Aglitti, Andrea, Xue, Zhenyi, Rullman, Janean, Porcalla, Ariel R., Cohen, Eric, Trinh, Roger N., and Persico, Marcello

Published

2018

69. THU-363 - Efficacy and safety of glecaprevir/pibrentasvir in renally-impaired patients with chronic hepatitis C virus genotype 1–6 infection

Author

Persico, M., Flisiak, R., Abunimeh, M., Sise, M., Park, J.Y., Kaskas, M., Bruchfeld, A., Wörns, M.-A., Aglitti, A., Xue, Z., Rullman, J., Pocalla, A., and Lawitz, E.

Published

2018

70. EP-1771: Evaluation Of Skin Dose Changes Using Tld For Head And Neck Patients Treated With Helicaltomotherapy

Author

Yilmaz, E., Ertan, F., Akkas, E., Dizman, A., Hicsonmez, A., and Kaskas, A.

Published

2018

71. Global properties ofKhindrance probed by theγdecay of the warm rotating174W nucleus

Author

Luna Pellegri, C. A. Ur, B. Million, O. Stezowski, V. Vandone, J. Grebosz, R. Menegazzo, A. Kaşkaş, F. Camera, A. Atac, S. Lunardi, A. Giaz, D. Mengoni, C. Michelagnoli, D. Montanari, D. S. Judson, Andreas Görgen, Herbert Hess, B. Birkenbach, P. Reiter, J. J. Valiente-Dobón, D. R. Napoli, Enrico Calore, S. Leoni, S. Brambilla, P. J. Coleman-Smith, G. de Angelis, E. Sahin, M. D. Salsac, R. Nicolini, E. Vigezzi, A. Gottardo, A. Obertelli, F. Recchia, Alberto Pullia, N. Karkour, F. C. L. Crespi, M. Matsuo, P. A. Söderström, P. J. Nolan, Bo Cederwall, Serkan Akkoyun, A. Jungclaus, D. Bazzacco, T. Hüyük, Damiano Bortolato, A. Gadea, M. Kmiecik, D. Rosso, E. Farnea, Ch. Theisen, Andrea Corsi, D. M. Cullen, P. Désesquelles, Marco Bellato, A. Maj, A. Bracco, G. Benzoni, S. Bottoni, N. Blasi, G. Maron, P. Molini, O. Wieland, J. Eberth, N. Cieplicka, and C. Boiano

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Gamma ray, Quantum number, 01 natural sciences, Excited state, 0103 physical sciences, Nuclear fusion, AGATA, Atomic physics, Multiplicity (chemistry), 010306 general physics, Mixing (physics), Excitation

Abstract

The K hindrance to the gamma decay is studied in the warm rotating W-174 nucleus, focusing on the weakening of the selection rules of the K quantum number with increasing excitation energy. W-174 was populated by the fusion reaction of Ti-50 (at 217 MeV) on a Te-128 target, and its gamma decay was detected by the AGATA Demonstrator array coupled to a BaF2 multiplicity filter at Laboratori Nazionali di Legnaro of INFN. A fluctuation analysis of gamma coincidence matrices gives a similar number of low-K and high-K discrete excited bands. The results are compared to simulations of the gamma-decay flow based on a microscopic cranked shell model at finite temperature in which the K mixing is governed by the interplay of Coriolis force with the residual interaction. Agreement between simulations and experiment is obtained only by hindering the E1 decay between low-K and high-K bands by an amount compatible with that determined by spectroscopic studies of K isomers in the same mass region, with a similar trend with excitation energy. The work indicates that K mixing due to temperature effects may play a leading role for the entire body of discrete excited bands, which probes the onset region of K weakening.

Published

2013

72. Identification and rejection of scattered neutrons in AGATA

Author

E. Farnea, A. Atac, Serkan Akkoyun, Johan Nyberg, F. C. L. Crespi, A. Kaşkaş, S. Brambilla, F. Camera, P. A. Söderström, D. Mengoni, R.S. Kempley, M. Palacz, Luna Pellegri, M. Şenyiğit, D. Bazzacco, J. J. Valiente Dobon, A. Giaz, A. Gottardo, E. Sahin, J. Ljungvall, Stefano Riboldi, C. Michelagnoli, B. Million, F. Recchia, Istituto Nazionale di Fisica Nucleare, Sezione di Padova (INFN, Sezione di Padova), Istituto Nazionale di Fisica Nucleare (INFN), Dipartimento di Fisica, Universita degli Studi di Padova, CSNSM SNO, Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Centre de Spectrométrie Nucléaire et de Spectrométrie de Masse (CSNSM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), School of Engineering, University of the West of Scotland (UWS), [Senyigit, M. -- Atac, A. -- Kaskas, A.] Ankara Univ, Fac Sci, Dept Phys, TR-06100 Ankara, Turkey -- [Atac, A.] Royal Inst Technol, Dept Phys, SE-10691 Stockholm, Sweden -- [Akkoyun, S.] Cumhuriyet Univ, Dept Phys, Fac Sci, TR-58140 Sivas, Turkey -- [Bazzacco, D. -- Recchia, F. -- Farnea, E. -- Mengoni, D. -- Michelagnoli, C.] Ist Nazl Fis Nucl, Sez Padova, I-35131 Padua, Italy -- [Bazzacco, D. -- Recchia, F. -- Farnea, E. -- Michelagnoli, C.] Univ Padua, Dipartimento Fis & Astron, I-35131 Padua, Italy -- [Nyberg, J. -- Soderstrom, P. A.] Uppsala Univ, Dept Phys & Astron, SE-75120 Uppsala, Sweden -- [Brambilla, S. -- Camera, F. -- Crespi, F. C. L. -- Giaz, A. -- Million, B. -- Pellegri, L. -- Riboldi, S.] Ist Nazl Fis Nucl, Sez Milano, I-20133 Milan, Italy -- [Camera, F. -- Pellegri, L. -- Riboldi, S.] Univ Milan, I-20133 Milan, Italy -- [Gottardo, A. -- Sahin, E. -- Dobon, J. J. Valiente] Ist Nazl Fis Nucl, Lab Nazl Legnaro, I-35020 Legnaro, PD, Italy -- [Kempley, R.] Univ Surrey, Dept Phys, Guildford GU2 7XH, Surrey, England -- [Ljungvall, J.] CNRS, IN2P3, CSNSM, F-91405 Orsay, France -- [Ljungvall, J.] Univ Paris 11, F-91405 Orsay, France -- [Mengoni, D.] Univ West Scotland, Nucl Phys Res Grp, Paisley PA1 2BE, Renfrew, Scotland -- [Palacz, M.] Univ Warsaw, Heavy Ion Lab, PL-02093 Warsaw, Poland -- [Soderstrom, P. A.] RIKEN, Nishina Ctr, Wako, Saitama 3510198, Japan, senyigit, menekse -- 0000-0002-2408-4419, Soderstrom, Par-Anders -- 0000-0002-9504-2814, GOTTARDO, Andrea -- 0000-0002-0390-5767, Camera, Franco -- 0000-0003-1731-4834, Sahin, Eda -- 0000-0003-0683-5140, Recchia, Francesco -- 0000-0002-8428-0112, Pellegri, Luna -- 0000-0002-3227-3332, GIAZ, Agnese -- 0000-0002-2550-450X, Centre de Spectrométrie Nucléaire et de Spectrométrie de Masse (CSNSM), and Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM)

Subjects

Nuclear and High Energy Physics, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, AGATA, High-purity germanium, High-purity germanium detector, Interaction points, Ray tracking, Segmented HPGe detectors, Spontaneous fission, Time of flight measurements, Barium compounds, Detectors, Experiments, Germanium, Neutron scattering, Tracking (position), Neutrons, 252Cf, Inelastic scattering, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], gamma-Ray tracking, Nuclear physics, Cf-252, Neutron detection, Neutron, AGATA, High-purity germanium, High-purity germanium detector, Interaction points, Ray tracking, Segmented HPGe detectors, Spontaneous fission, Time of flight measurements, Barium compounds, Detectors, Experiments, Germanium, Neutron scattering, Tracking (position), Nuclear Experiment (nucl-ex), Nuclear Experiment, Instrumentation, Physics, Elastic scattering, Geant4 Simulations, Neutron-gamma discrimination, Gamma ray, Neutron-Gamma Discrimination, Gamma-Ray Tracking, Time-of-Flight (TOF)

Abstract

WOS: 000327494600037, gamma Rays and neutrons, emitted following spontaneous fission of Cf-252, were measured in an AGATA experiment performed at INFN Laboratori Nazionali di Legnaro in Italy. The setup consisted of four AGATA triple cluster detectors (12 36 fold segmented high purity germanium crystals), placed at a distance of 50 cm from the source, and 16 HELENA BaF2 detectors. The aim of the experiment was to study the interaction of neutrons in the segmented high purity germanium detectors of AGATA and to investigate the possibility to discriminate neutrons and gamma rays with the gamma-ray tracking technique. The BaF2 detectors were used for a time measurement, which gave an independent discrimination of neutrons and gamma rays and which was used to optimise the gamma-ray tracking based neutron rejection methods. It was found that standard gamma-ray tracking, without any additional neutron rejection features, eliminates effectively most of the interaction points clue to recoiling Ge nuclei after elastic scattering of neutrons. Standard Cracking rejects also a significant amount of the events due to inelastic scattering of neutrons in the germanium crystals. Further enhancements of the neutron rejection was obtained by setting conditions on the following quantities, which were evaluated for each event by the Cracking algorithm: energy of the first and second interaction point, difference in the calculated incoming direction of the gamma ray, and figure-of-merit value. The experimental results of Cracking with neutron rejection agree rather well with GEANT4 simulations. (C) 2013 Elsevier B.V. All rights reserved., Scientific and Technological Council of Turkey [106T055]; Swedish Research Council, This work was partly supported by the Scientific and Technological Council of Turkey (project number 106T055) and by the Swedish Research Council

Published

2013

73. The slab albedo problem using singular eigenfunctions and the third form of the transport equation

Author

A. Kaşkaş, M. Ç. Güleçyüz, and Cevdet Tezcan

Subjects

Nuclear Energy and Engineering, Simple (abstract algebra), Convergence (routing), Mathematical analysis, Slab, Neutron, Function (mathematics), Albedo, Eigenfunction, Convection–diffusion equation, Mathematics

Abstract

The albedo and the transmission factor for slabs are obtained using the infinite medium Green's function in terms of the singular eigenfunctions in the third form of the transport equation. Our analytical results are simple as in the F N method and the convergence of the numerical results is as fast as in the C N method. Calculations are also carried out by various incoming angular fluxes and uncollided neutrons are taken into account. Our numerical results are in very good agreement with the results of the C N method and, as shown in the tables, are obtained up to the eighth order of approximation.

Published

1996

74. Solution of the CN equations using singular eigenfunctions and applications

Author

A. Kaşkaş, M. Ç. Güleçyüz, Cevdet Tezcan, and F. Erdog̈an

Subjects

Laplace's equation, Partial differential equation, Diffusion equation, Nuclear Energy and Engineering, Integro-differential equation, Differential equation, Mathematical analysis, Functional equation, Heat equation, Green's function for the three-variable Laplace equation, Mathematics

Abstract

The third form of Boltzmann equation involves only the angular flux at the boundary while the usual transport equation deals with the angular flux at any point. The kernel of this equation is the infinite medium Green's function and satisfies the lineer transport equation. The method of solution of this equation is known as the CN method and is based on the Placzek lemma and depends on the calculation of the infinite medium Green's function. Here, the well-known form of the Green's function in terms of elementary solutions is used to solve the third form of the transport equation and applications for the half-space albedo problems for both isotropic and extremely anisotropic scatterings are given. Uncollided neutrons are also taken into account.

Published

1996

75. The FN method for anisotropic scattering in neutron transport theory: The half-space problems

Author

A. Kaşkaş and Cevdet Tezcan

Subjects

Physics, Anisotropic scattering, Radiation, Neutron transport theory, Classical mechanics, Astrophysics::Earth and Planetary Astrophysics, Half-space, Albedo, Constant (mathematics), Spectroscopy, Atomic and Molecular Physics, and Optics, Computational physics

Abstract

The FN method is extended for problems for extremely anisotropic scattering and applied to the half-space albedo and the constant source problems.

Published

1996

76. Influence of thenpinteraction on theβdecay of94Pd

Author

P. J. Woods, S. Pietri, M. Górska, P. Reiter, N. Warr, P. H. Regan, C. Nociforo, Pär-Anders Söderström, Reiner Kruecken, H. Grawe, Zhi Liu, N. Braun, N. Kurz, K. Geibel, E. Merchan, C. Scholl, A. Prochazka, Robert Hoischen, Roman Gernhaeuser, Zs. Podolyák, N. Goel, Dirk Rudolph, F. Nowacki, J. Grebosz, R. Wadsworth, T. S. Brock, Johan Nyberg, C. Hinke, Sami Rinta-Antila, H. Iwasaki, A. Kaşkaş, J. Jolie, I. Kojouharov, T. Faestermann, L. Bettermann, T. Engert, M. Pfuetzner, B. S. Nara Singh, H. J. Wollersheim, A. Gottardo, C. Domingo-Pardo, Helmut Weick, F. Farinon, P. Boutachkov, H. Schaffner, J. Gerl, A. Blazhev, A. Atac, S. J. Steer, F. Finke, G. Ilie, and L. Caceres

Subjects

Physics, Nuclear and High Energy Physics, Atomic orbital, Fragmentation (mass spectrometry), Isotope, SHELL model, Structural transition, Atomic physics, Beta decay

Abstract

We present results from stopped beam rare isotope spectroscopic investigations at the GSI (RISING) experiment based on the detection of gamma-ray transitions following the beta decay of Pd-94. A comparison between the measured low-lying level scheme of Rh-94 and the prediction from shell-model calculations reveals the important roles of the g(7/2) and g(9/2) orbitals in explaining the structural features. The low values of the Gamow-Teller strengths B(GT) can be attributed to the influence of the neutron-proton interaction, which gives rise to an increased seniority mixing for the nuclear states, thereby leading to a fragmentation of the strength to several daughter levels. These results provide further strong indications that Pd-94 resides in the middle of a structural transition region in the Pd isotopes as the N = Z line is approached.

Published

2012

77. Superallowed Gamow-Teller decay of the doubly magic nucleus $^{100}$Sn

Author

H. J. Wollersheim, K. Straub, N. Alkhomashi, Johan Nyberg, S. Pietri, A. Prochazka, C. Nociforo, Zhi Liu, S. Nishimura, G. F. Farrelly, S. Schwertel, F. Nebel, Igor T. Čeliković, A. Kaşkaş, I. Kojouharov, P. Strmeň, C. Scheidenberger, Zs. Podolyák, Hans Geissel, J. Grebosz, F. Farinon, Catherine Rigollet, C. Hinke, T. Habermann, T. Faestermann, J. Gerl, A. R. Parikh, Philip Woods, Y. Litvinov, R. Krücken, H. Grawe, P. Doornenbal, Iris Dillmann, N. Kurz, N. Braun, K. Steiger, Roman Gernhäuser, H. Schaffner, K. Sieja, M. Böhmer, Andreas Stolz, Th. Kröll, A. Blazhev, R. Janik, A. Atac, S. J. Steer, S. Myalski, Robert Hoischen, L. Maier, N. Al-Dahan, N. Goel, Thomas Davinson, P. Boutachkov, A. Gottardo, M. Górska, C. Domingo-Pardo, Helmut Weick, M. Karny, F. Nowacki, P. H. Regan, P. A. Söderström, Institut Pluridisciplinaire Hubert Curien (IPHC), Université de Strasbourg (UNISTRA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Grand Accélérateur National d'Ions Lourds (GANIL), Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3), Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, Multidisciplinary, Proton, 010308 nuclear & particles physics, Proton decay, Nuclear Theory, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, Beta decay, Nuclear physics, Decay energy, 0103 physical sciences, Atomic nucleus, Physical Sciences, Fysik, Neutron, Atomic physics, 010306 general physics, Nucleon, Nuclear Experiment, Radioactive decay

Abstract

Expérience au GSI; The shell structure of atomic nuclei is associated with 'magic numbers' and originates in the nearly independent motion of neutrons and protons in a mean potential generated by all nucleons. During b1-decay, a proton transforms into a neutron in a previously not fully occupied orbital, emitting a positron-neutrino pair with either parallel or antiparallel spins, in a Gamow-Teller or Fermi transition, respectively. The transition probability, or strength, of a Gamow-Teller transition depends sensitively on the underlying shell structure and is usually distributed among many states in the neighbouring nucleus. Here we report measurements of the half-life and decay energy for the decay of 100Sn, the heaviest doubly magic nucleus with equal numbers of protons and neutrons. In the b-decay of 100Sn, a large fraction of the strength is observable because of the large decay energy. We determine the largest Gamow-Teller strength so far measured in allowed nuclear b-decay, establishing the 'superallowed' nature of this Gamow-Teller transition. The large strength and the low-energy states in the daughter nucleus, 100In, are well reproduced by modern, large-scale shell model calculations.

Published

2012

78. 16+Spin-Gap Isomer inCd96

Author

B. S. Nara Singh, H. J. Wollersheim, P. Reiter, I. Kojouharov, L. Caceres, Dirk Rudolph, J. Grebosz, T. S. Brock, Johan Nyberg, S. Pietri, H. Iwasaki, K. Geibel, C. Hinke, K. Sieja, J. Jolie, N. Warr, A. Gottardo, Robert Hoischen, T. Engert, F. Nowacki, Sami Rinta-Antila, K. Eppinger, N. Braun, C. Nociforo, E. Merchan, A. Kaşkaş, N. Kurz, F. Farinon, Zhi Liu, P. A. Söderström, P. J. Woods, A. Atac, A. Prochazka, Reiner Kruecken, Roman Gernhaeuser, R. Wadsworth, S. J. Steer, P. H. Regan, C. Scholl, M. Pfuetzner, N. Goel, C. Domingo-Pardo, Helmut Weick, H. Schaffner, A. Blazhev, L. Bettermann, F. Finke, G. Ilie, Zs. Podolyák, J. Gerl, Thomas Faestermann, H. Grawe, M. Górska, and P. Boutachkov

Subjects

Physics, medicine.anatomical_structure, Isotope, Stable isotope ratio, Isoscalar, Isotopes of cadmium, Gamma ray, medicine, General Physics and Astronomy, Atomic physics, Nucleus, Beta decay, Radioactive decay

Abstract

A beta-decaying high-spin isomer in Cd-96, with a half-life T-1/2 = 0.29(-0.10)(+0.11) s, has been established in a stopped beam rare isotope spectroscopic investigations at GSI (RISING) experiment. The nuclei were produced using the fragmentation of a primary beam of Xe-124 on a Be-9 target. From the half-life and the observed gamma decays in the daughter nucleus, Ag-96, we conclude that the beta-decaying state is the long predicted 16(+) "spin-gap'' isomer. Shell-model calculations, using the Gross-Frenkel interaction and the pi nu(p(1/2,)g(9/2)) model space, show that the isoscalar component of the neutron-proton interaction is essential to explain the origin of the isomer. Core excitations across the N = Z = 50 gaps and the Gamow-Teller strength, Bd(GT) distributions have been studied via large-scale shell-model calculations using the pi nu(g, d, s) model space to compare with the experimental B(GT) value obtained from the half-life of the isomer. (Less)

Published

2011

79. 16+ spin-gap isomer in Cd96

Author

Nara Singh, BS, Liu, Z, Wadsworth, R, Grawe, H, Brock, TS, Boutachkov, P, Braun, N, Blazhev, A, Górska, M, Pietri, S, Rudolph, D, Domingo-Pardo, C, Steer, SJ, Ataç, A, Bettermann, L, Cáceres, L, Eppinger, K, Engert, T, Faestermann, T, Farinon, F, Finke, F, Geibel, K, Gerl, J, Gernhäuser, R, Goel, N, Gottardo, A, Grabosz, J, Hinke, C, Hoischen, R, Ilie, G, Iwasaki, H, Jolie, J, Kaşkaş, A, Kojouharov, I, Krücken, R, Kurz, N, Merchán, E, Nociforo, C, Nyberg, J, Pfützner, M, Prochazka, A, Podolyák, Z, Regan, PH, Reiter, P, Rinta-Antila, S, Scholl, C, Schaffner, H, Söderström, P-A, Warr, N, Weick, H, Wollersheim, H-J, Woods, PJ, Nowacki, F, and Sieja, K

Published

2011

80. Exotic nuclear studies around and below A = 100

Author

B. S. Nara Singh, R. Wadsworth, P. Boutachkov, A. Blazhev, Z. Liu, H. Grawe, T. S. Brock, N. Braun, M. Go, S. Pietri, D. Rudolph, C. Domingo-Pardo, S. J. Steer, A. Atac, L. Bettermann, L. Cáceres, K. Eppinger, T. Engert, T. Faestermann, F. Farinon, F. Finke, K. Geibel, J. Gerl, R. Gernhäuser, N. Goel, A. Gottardo, J. Grȩbosz, C. Hinke, R. Hoischen, G. llie, H. Iwasaki, J. Jolie, A. Kaşkaş, I. Kojouharov, R. Krücken, N. Kurz, E. Merchánt, C. Nociforo, J. Nyberg, M. Pfützner, A. Prochazka, Zs. Podolyák, P. H Regan, P. Reiter, S. Rinta-Antila, C. Scholl, H. Schaffner, P.-A. Söderström, N. Warr, H. Weick, H.-J. Wollersheim, P. J. Woods, F. Nowacki, K. Sieja, and Bertram Blank

Subjects

Nuclear physics, Physics, Nuclear Theory, SHELL model, Nuclear structure, Gamma spectroscopy, Context (language use), Nuclear Experiment, Spin (physics)

Abstract

A RISING experiment with an aim to study exotic Cd nuclei was carried out at GSI‐FRS facility. Some preliminary results from this experiment are presented here. In particular, the β decay of 96Cd to 96Ag revealed the existence of a high spin isomer predicted a few decades ago. In this context, the structures of both these nuclei are discussed. Shell model calculations using the Gross‐Frenkel interaction are used to interpret the results.

Published

2011

81. Observation of a new high-spin isomer inPd94

Author

N. Goel, M. Górska, P. Boutachkov, H. J. Wollersheim, A. Gottardo, C. Domingo-Pardo, Helmut Weick, Zhi Liu, K. Eppinger, Johan Nyberg, L. Caceres, Dirk Rudolph, A. Atac, T. S. Brock, A. Kaşkaş, Zs. Podolyák, J. Gerl, I. Kojuharov, Thomas Faestermann, J. Grebosz, S. J. Steer, J. Jolie, M. Pfuetzner, P. Reiter, P. J. Woods, F. Farinon, N. Warr, H. Iwasaki, C. Hinke, P. H. Regan, N. Kurz, H. Grawe, T. Engert, A. Prochazka, L. Bettermann, S. Pietri, Reiner Kruecken, C. Nociforo, N. Braun, K. Geibel, A. Blazhev, Pär-Anders Söderström, Sami Rinta-Antila, C. Scholl, E. Merchan, Robert Hoischen, R. Gernhaeuser, B. S. Nara Singh, R. Wadsworth, H. Schaffner, F. Finke, and G. Ilie

Subjects

Physics, Nuclear and High Energy Physics, Atomic orbital, Isotope, Isotopes of palladium, Isotopes of tin, Gamma ray, Half-life, Nuclide, Atomic physics, Radioactive decay

Abstract

A second gamma-decaying high-spin isomeric state, with a half-life of 197(22) ns, has been identified in the N = Z + 2 nuclide Pd-94 as part of a stopped-beam Rare Isotope Spectroscopic INvestigation at GSI (RISING) experiment. Weisskopf estimates were used to establish a tentative spin/parity of 19(-), corresponding to the maximum possible spin of a negative parity state in the restricted (p(1/2), g(9/2)) model space of empirical shell model calculations. The reproduction of the E3 decay properties of the isomer required an extension of the model space to include the f (5/2) and p(3/2) orbitals using the CD-Bonn potential. This is the first time that such an extension has been required for a high-spin isomer in the vicinity of Sn-100 and reveals the importance of such orbits for understanding the decay properties of high-spin isomers in this region. However, despite the need for the extended model space for the E3 decay, the dominant configuration for the 19(-) state remains (p p(1/2)(-1)g(9/2)(-3))(11)circle times(nu g(9/2)(-2))(8). The half-life of the known, 14(+), isomer was remeasured and yielded a value of 499(13) ns.

Published

2010

82. Observation of a new high-spin isomer in Pd94

Author

Brock, TS, Nara Singh, BS, Boutachkov, P, Braun, N, Blazhev, A, Liu, Z, Wadsworth, R, Górska, M, Grawe, H, Pietri, S, Domingo-Pardo, C, Rudolph, D, Steer, SJ, Ataç, A, Bettermann, L, Cáceres, L, Engert, T, Eppinger, K, Faestermann, T, Farinon, F, Finke, F, Geibel, K, Gerl, J, Gernhäuser, R, Goel, N, Gottardo, A, Grȩbosz, J, Hinke, C, Hoischen, R, Ilie, G, Iwasaki, H, Jolie, J, Kaşkaş, A, Kojuharov, I, Krücken, R, Kurz, N, Merchán, E, Nociforo, C, Nyberg, J, Pfützner, M, Prochazka, A, Podolyák, Z, Regan, PH, Reiter, P, Rinta-Antila, S, Schaffner, H, Scholl, C, Söderström, P-A, Warr, N, Weick, H, Wollersheim, H-J, and Woods, PJ

Published

2010

83. Discrimination of gamma rays due to inelastic neutron scattering in AGATA

Author

Serkan Akkoyun, Johan Nyberg, M. Şenyiğit, A. Kaşkaş, S. O. Kara, T. Hüyük, and A. Atac

Subjects

Physics, Nuclear and High Energy Physics, Spectrometer, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Gamma ray, FOS: Physical sciences, Inelastic scattering, Tracking (particle physics), 01 natural sciences, Inelastic neutron scattering, Nuclear physics, 0103 physical sciences, Neutron, AGATA, Nuclear Experiment (nucl-ex), 010306 general physics, Hpge detector, Nuclear Experiment, Instrumentation

Abstract

Possibilities of discriminating neutrons and gamma rays in the AGATA gamma-ray tracking spectrometer have been investigated with the aim of reducing the background due to inelastic scattering of neutrons in the high-purity germanium crystals. This background may become a serious problem especially in experiments with neutron-rich radioactive ion beams. Simulations using the Geant4 toolkit and a tracking program based on the forward tracking algorithm were carried out by emitting neutrons and gamma rays from the center of AGATA. Three different methods were developed and tested in order to find 'fingerprints' of the neutron interaction points in the detectors. In a simulation with simultaneous emission of six neutrons with energies in the range 1-5 MeV and ten gamma rays with energies between 150 and 1450 keV, the peak-to-background ratio at a gamma-ray energy of 1.0 MeV was improved by a factor of 2.4 after neutron rejection with a reduction of the photopeak efficiency at 1.0 MeV of only a factor of 1.25., Accepted for publication in Nuclear Instruments and Methods in Physics Research, A, 26 May 2009; 13 pages, 5 tables, 12 figures

Published

2009

84. The H-N method for half-space Albedo and constant source problems for isotropic and anisotropic scattering kernels

Author

M. Ç. Güleçyüz, R. G. Türeci, A. Kaşkaş, and Cevdet Tezcan

Subjects

Physics, Radiation, business.industry, constant source, Isotropy, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Albedo, Half-space, anisotropic scattering, neutron transport theory, Atomic and Molecular Physics, and Optics, Computational physics, Anisotropic scattering, Optics, Neutron transport theory, Isotropic scattering, isotropic scattering, business, Constant (mathematics), Spectroscopy, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

Tureci, RG/0000-0001-6309-6300; gulecyuz, mustafa cetin/0000-0002-8838-7400 WOS: 000242562100015 The H-N method, which is developed recently, is used to solve the half-space albedo and the half-space constant source problems for both isotropic and extremely anisotropic scattering kernels. It has been shown that the method solves the problems in a concise manner and leads to fast converging numerical results as shown in tables. (c) 2006 Elsevier Ltd. All rights reserved.

Published

2007

85. Analytic algorithms for determining radiative transfer optical properties of ocean waters

Author

Cevdet Tezcan, M. Ç. Güleçyüz, Norman J. McCormick, and A. Kaşkaş

Subjects

Physics, Computer simulation, Forward scatter, business.industry, Scattering, Materials Science (miscellaneous), Dirac delta function, Inverse problem, Industrial and Manufacturing Engineering, Collimated light, Algebraic equation, symbols.namesake, Optics, symbols, Radiative transfer, Business and International Management, business, Algorithm

Abstract

A synthetic model for the scattering phase function is used to develop simple algebraic equations, valid for any water type, for evaluating the ratio of the backscattering to absorption coefficients of spatially uniform, very deep waters with data from upward and downward planar irradiances and the remotely sensed reflectance. The phase function is a variable combination of a forward-directed Dirac delta function plus isotropic scattering, which is an elementary model for strongly forward scattering such as that encountered in oceanic optics applications. The incident illumination at the surface is taken to be diffuse plus a collimated beam. The algorithms are compared with other analytic correlations that were previously derived from extensive numerical simulations, and they are also numerically tested with forward problem results computed with a modified FN method.

Published

2006

86. The effect of extremely anisotropic scattering on the critical slab problem in one-speed neutron transport theory

Author

Karahasanoğlu Şenyiğit, M., Kaşkaş, A., and Bölüm Yok

Subjects

Neutrons, Extremely anisotropic scattering, Critical slab problem, Nötronlar, Aşırı anizotropik saçılm, One-speed neutron transport theory, Tek-hızlı nötron taşınım teorisi, Kritik slab problemi

Abstract

To solve the critical slab problem, the infinite medium Green’s function for the anisotropic scattering obtained in terms of the infinite medium Green’s function for the isotropic scattering is used in the analytical expressions of exit distributions in FN method. The numerical calculations performed using HN method. The convergence of our numerical results is better than FN method. anın üzerindeki etkisi

Published

2006

87. The solution of third form of the transport equation using the singular eigenfunction method: constant source problem

Author

Kaşkaş, A., Güleçyüz, M. C., Türeci, G., and Bölüm Yok

Subjects

Transport equation, Sabit kaynak problemi, Constant source problem, Tekil özfonksiyon yöntemi, Taşıma denklemi, Singular eigenfunction method

Abstract

The third form of the transport equation has been solved using CN method. In this method the infinite medium Green’s function which has been obtained from Fourier transform technique was used. The singular eigenfunction method is based on the use of the infinite medium Green’s function. The method which we want to use in this calculation is based on the infinite medium Green’s function. This function can be written in terms of singular eigenfunctions of the Case’s method. This method leads to obtain analytical expression of the problem easily. The numerical results are in good agreement with FN method. International Atomic Energy Agency

Published

2006

88. On a problem with extremely anisotropic scattering in slab

Author

Kaşkaş, A., Karahasanoğlu, M., and Bölüm Yok

Subjects

Levha, Extremely anisotropic scattering, Anizotropik saçılma sorunu, Slab

Abstract

The slab albedo problem will be solved for the extremely anisotropic scattering function using the analytical expressions of Fn method with a different numerical approximation. The infinite medium Green’s function for the anisotropic scattering obtained in terms of the infinite medium Green’s function for the isotropic scattering is used. The albedo and transmission factor for a slab are calculated and the numerical results are compared with data available in the literature. Döşemede aşırı

Published

2006

89. The singular eigenfunction method: The critical slab problem for linearly anisotropic scattering (Rewiew)

Author

Türeci R.G., Güleçyüz M.Ç., Kaşkaş A., Tezcan C., and Kırıkkale Üniversitesi

Abstract

The critical slab problem for linearly anisotropic scattering is investigated using the singular eigenfunction method. The third form of the transport equation is considered. The singular eigenfunctions for linearly anisotropic scattering are inserted into the Green's function. This Green's function with the full range orthogonality relations of the singular eigenfunctions together with the appropriate boundary conditions provide the criticality equation. This equation is exact and leads as shown in tables to fast converging numerical results. © Carl Hanser Verlag, München.

Published

2005

90. List of Contributors

Author

Baker-Ericzén, Mary, Brookman-Frazee, Lauren, Chlebowski, Colby, Conner, Caitlin M., Danial, John, Davis, Thompson E., Donnelly, James P., Drahota, Amy, Fujii, Cori, Hagopian, Louis P., Herrington, John D., Kaskas, Maysa M., Kendall, Philip C., Kent, Rachel, Kerns, Connor M., Klebanoff, Sami, Lerner, Matthew D., Levine, Karen, Lilly, Megan, Lopata, Christopher, Maddox, Brenna B., Magiati, Iliana, Miller, Judith S., Moskowitz, Lauren J., Ozsivadjian, Ann, Parma, Valentina, Reaven, Judy, Renno, Patricia, Rosen, Tamara, Ryan, Paige M., Simonoff, Emily, Stadnick, Nicole, Storch, Eric A., Thomeer, Marcus L., White, Susan W., Willar, Kirsten, and Wood, Jeffrey J.

Published

2017

91. The singular eigenfunction method: the milne problem for isotropic and extremely anisotropic scattering

Author

Kaşkaş, A., Güleçyüz, M. Ç., Erdoğan, F., Tezcan, C., and Bölüm Yok

Subjects

Mil problemi, İzotropik ve aşırı anizotropik saçılma, Isotropic and extremely anisotropic scattering, Tekil özfonksiyon yöntemi, Milne problem, Singular eigenfunction method

Abstract

I. Avrasya Nükleer Bilimler ve Uygulamaları Konferansı : 23-27 Ekim 2000. İzmir, Türkiye. In the CN method of solving the third form of the transport equation, the medium as a result of Placzek lemma is extend to infinity. Infinite medium Green function which is obtained by the Fourier transform technique is used and the method is applied to one velocity problems in plane and cylindrical geometries. As the result of physical applications of the CN method in different geometries, it is seen that the only difficulty lies in writting the expression of the Green’s function in a form easy to handle. In the new method of solving of the third form of the transport equation (that we have generated recently), three methods, namely, CN, FN and the method of elementary solutions are considered, compared and the Green function in terms of the singular eigenfunctions is used. This method yields simple analytical expressions that can be solved numerically more efficiently than the CN method because the expression of the Green function is in the form easy to handle. Here this new method is applied to calculate the extrapolation length for the Milne problem which is classical problem in astrophysics concerned with the diffusion of radiation through a stellar atmosphere for both isotropic and extremely anisotropic scatterings. It is shown that the numerical results which are tabulated for selected cases are accurate even in the approximations of the lowest order and are in good agreement with the numerical results obtained by the other methods.

Published

2000

92. Observation of a new high-spin isomer in $^{94}\mathrm{Pd}$

Author

Brock, T. S., Nara Singh, B. S., Boutachkov, P., Braun, N., Blazhev, A., Liu, Z., Wadsworth, R., Górska, M., Grawe, H., Pietri, S., Domingo-Pardo, C., Rudolph, D., Steer, S. J., Ataç, A., Bettermann, L., Cáceres, L., Engert, T., Eppinger, K., Faestermann, T., Farinon, F., Finke, F., Geibel, K., Gerl, J., Gernhäuser, R., Goel, N., Gottardo, A., Grębosz, J., Hinke, C., Hoischen, R., Ilie, G., Iwasaki, H., Jolie, J., Kaşkaş, A., Kojuharov, I., Krücken, R., Kurz, N., Merchán, E., Nociforo, C., Nyberg, Johan, Pfützner, M., Prochazka, A., Podolyák, Zs., Regan, P. H., Reiter, P., Rinta-Antila, S., Schaffner, H., Scholl, C., Söderström, P. -A, Warr, N., Weick, H., Wollersheim, H. -J, Woods, P. J., Brock, T. S., Nara Singh, B. S., Boutachkov, P., Braun, N., Blazhev, A., Liu, Z., Wadsworth, R., Górska, M., Grawe, H., Pietri, S., Domingo-Pardo, C., Rudolph, D., Steer, S. J., Ataç, A., Bettermann, L., Cáceres, L., Engert, T., Eppinger, K., Faestermann, T., Farinon, F., Finke, F., Geibel, K., Gerl, J., Gernhäuser, R., Goel, N., Gottardo, A., Grębosz, J., Hinke, C., Hoischen, R., Ilie, G., Iwasaki, H., Jolie, J., Kaşkaş, A., Kojuharov, I., Krücken, R., Kurz, N., Merchán, E., Nociforo, C., Nyberg, Johan, Pfützner, M., Prochazka, A., Podolyák, Zs., Regan, P. H., Reiter, P., Rinta-Antila, S., Schaffner, H., Scholl, C., Söderström, P. -A, Warr, N., Weick, H., Wollersheim, H. -J, and Woods, P. J.

Published

2010

93. Discrimination of gamma rays due to inelastic neutron scattering in AGATA

Author

Atac Nyberg, Ayse, Kaşkaş, Ayşe, Akkoyun, Serkan, Şenyiğit, Menekse, Hüyük, Tayfun, Kara, S. Okan, Nyberg, Johan, Atac Nyberg, Ayse, Kaşkaş, Ayşe, Akkoyun, Serkan, Şenyiğit, Menekse, Hüyük, Tayfun, Kara, S. Okan, and Nyberg, Johan

Abstract

Possibilities of discriminating neutrons and γ rays in the AGATA γ-ray tracking spectrometer have been investigated with the aim of reducing the background due toinelastic scattering of neutrons in the high-purity germanium crystals. This background may become a serious problem especially in experiments with neutron-rich radioactive ion beams. Simulations using the Geant4 toolkit and a tracking program based on the forward tracking algorithm were carried out by emitting neutrons and γ rays from the center of AGATA. Three different methods were developed and tested in order to find "fingerprints" of the neutron interaction points in the detectors. In a simulation with simultaneous emission of six neutrons with energies in the range 1-5 MeV and 10 γ rayswith energies between 150 and 1450 keV, the peak-to-background ratio at a γ-ray energy of 1.0 MeV was improved by a factor of 2.4 after neutron rejection with a reduction of the photopeak efficiency at 1.0 MeV of only a factor of 1.25., QC 20120214

Published

2009

94. Identification and rejection of scattered neutrons in AGATA

Author

Şenyiğit, M., primary, Ataç, A., additional, Akkoyun, S., additional, Kaşkaş, A., additional, Bazzacco, D., additional, Nyberg, J., additional, Recchia, F., additional, Brambilla, S., additional, Camera, F., additional, Crespi, F.C.L., additional, Farnea, E., additional, Giaz, A., additional, Gottardo, A., additional, Kempley, R., additional, Ljungvall, J., additional, Mengoni, D., additional, Michelagnoli, C., additional, Million, B., additional, Palacz, M., additional, Pellegri, L., additional, Riboldi, S., additional, Şahin, E., additional, Söderström, P.A., additional, and Valiente Dobon, J.J., additional

Published

2014

95. İzotropik ve anizotropik saçılma için FN ve yeni geliştirilen bir yöntemle uygulamalar

Author

Kaşkaş, Ayşe, Tezcan, Cevdet, and Diğer

Subjects

Scattering, Fizik ve Fizik Mühendisliği, Physics and Physics Engineering

Abstract

Nötron transport denkleminin fiziksel uygulamaları isotropik ve anisotropik saçılma durumları için Case FN C N SN vb. yöntemler kullanılarak yapılmaktadır. Bu yöntemlerden Case yöntemi lineer transport denkleminin temel yöntemlerinden biridir. CN yöntemi ise sonlu ortam problemlerini sonsuz ortam problemine dönüştüren Placzek lemmasına dayanmaktadır. Çözümlerde Fourier dönüşüm tekniğinden elde edilen Green fonksiyonu kullanılır. Sonsuz ortam Green fonksiyonu aynı zamanda Case yönteminde de farklı bir şekilde çıkarılmıştır. CN yönteminde ortam sonsuz olduğuna göre Green fonksiyonu yerine Case yönteminden elde edilen sonsuz ortam Green fonksiyonu kullanılabilir. Bu şekilde geliştirilen yeni yaklaşım yöntemi ile slab-albedo problemi çözülmüş basit analitik ifadeler ve hızlı yakın sayan nümerik sonuçlar elde edilmişdir. Ayrıca Case'in singüler özfonk- siyonları cinsinden türetilen anisotropik saçılmalı Green fonksiyonu kullanılarak FN yöntemi ile yarı-uzay albedo problemi çözülmüştür. The physical applications of the neutron transport equation for both isotropic and anisotropic scattorlngs aro given by the Case FN Cn and Sn methods. The method known as the Case's method is one of the basic methods. The CN method is based on Placzek Lemma in which the finite medium problem is converted into the finite medium problem. In the application the Green's function obtained by the Fourier transporm technique is used. The different form of the infinite medium Green's function is given by the Case's approach. Therefore instead of Green's function obtained by the Fourier transform tech nique one can use the one obtained by the Case's method. Hence following this now approach we have solved the slab albedo problem. It Is shown that the analytical expressions are simple and the conver gence of tho numerical results is fast. The infinite medium Green's function for anisotropic scattering in terms of the Case's eigonfunc- tions is derived and used to solvo the half-space albedo problem with FN method. 80

Published

1998

96. Influence of thenpinteraction on theβdecay of94Pd

Author

Nara Singh, B. S., primary, Brock, T. S., additional, Wadsworth, R., additional, Grawe, H., additional, Boutachkov, P., additional, Braun, N., additional, Blazhev, A., additional, Liu, Z., additional, Górska, M., additional, Pietri, S., additional, Rudolph, D., additional, Domingo-Pardo, C., additional, Steer, S. J., additional, Ataç, A., additional, Bettermann, L., additional, Cáceres, L., additional, Engert, T., additional, Faestermann, T., additional, Farinon, F., additional, Finke, F., additional, Geibel, K., additional, Gerl, J., additional, Gernhäuser, R., additional, Goel, N., additional, Gottardo, A., additional, Grębosz, J., additional, Hinke, C., additional, Hoischen, R., additional, Ilie, G., additional, Iwasaki, H., additional, Jolie, J., additional, Kaşkaş, A., additional, Kojouharov, I., additional, Krücken, R., additional, Kurz, N., additional, Merchán, E., additional, Nociforo, C., additional, Nyberg, J., additional, Pfützner, M., additional, Prochazka, A., additional, Podolyák, Zs., additional, Regan, P. H., additional, Reiter, P., additional, Rinta-Antila, S., additional, Scholl, C., additional, Schaffner, H., additional, Söderström, P.-A., additional, Warr, N., additional, Weick, H., additional, Wollersheim, H.-J., additional, Woods, P. J., additional, and Nowacki, F., additional

Published

2012

97. AGATA—Advanced GAmma Tracking Array

Author

Akkoyun, S., primary, Algora, A., additional, Alikhani, B., additional, Ameil, F., additional, de Angelis, G., additional, Arnold, L., additional, Astier, A., additional, Ataç, A., additional, Aubert, Y., additional, Aufranc, C., additional, Austin, A., additional, Aydin, S., additional, Azaiez, F., additional, Badoer, S., additional, Balabanski, D.L., additional, Barrientos, D., additional, Baulieu, G., additional, Baumann, R., additional, Bazzacco, D., additional, Beck, F.A., additional, Beck, T., additional, Bednarczyk, P., additional, Bellato, M., additional, Bentley, M.A., additional, Benzoni, G., additional, Berthier, R., additional, Berti, L., additional, Beunard, R., additional, Lo Bianco, G., additional, Birkenbach, B., additional, Bizzeti, P.G., additional, Bizzeti-Sona, A.M., additional, Le Blanc, F., additional, Blasco, J.M., additional, Blasi, N., additional, Bloor, D., additional, Boiano, C., additional, Borsato, M., additional, Bortolato, D., additional, Boston, A.J., additional, Boston, H.C., additional, Bourgault, P., additional, Boutachkov, P., additional, Bouty, A., additional, Bracco, A., additional, Brambilla, S., additional, Brawn, I.P., additional, Brondi, A., additional, Broussard, S., additional, Bruyneel, B., additional, Bucurescu, D., additional, Burrows, I., additional, Bürger, A., additional, Cabaret, S., additional, Cahan, B., additional, Calore, E., additional, Camera, F., additional, Capsoni, A., additional, Carrió, F., additional, Casati, G., additional, Castoldi, M., additional, Cederwall, B., additional, Cercus, J.-L., additional, Chambert, V., additional, El Chambit, M., additional, Chapman, R., additional, Charles, L., additional, Chavas, J., additional, Clément, E., additional, Cocconi, P., additional, Coelli, S., additional, Coleman-Smith, P.J., additional, Colombo, A., additional, Colosimo, S., additional, Commeaux, C., additional, Conventi, D., additional, Cooper, R.J., additional, Corsi, A., additional, Cortesi, A., additional, Costa, L., additional, Crespi, F.C.L., additional, Cresswell, J.R., additional, Cullen, D.M., additional, Curien, D., additional, Czermak, A., additional, Delbourg, D., additional, Depalo, R., additional, Descombes, T., additional, Désesquelles, P., additional, Detistov, P., additional, Diarra, C., additional, Didierjean, F., additional, Dimmock, M.R., additional, Doan, Q.T., additional, Domingo-Pardo, C., additional, Doncel, M., additional, Dorangeville, F., additional, Dosme, N., additional, Drouen, Y., additional, Duchêne, G., additional, Dulny, B., additional, Eberth, J., additional, Edelbruck, P., additional, Egea, J., additional, Engert, T., additional, Erduran, M.N., additional, Ertürk, S., additional, Fanin, C., additional, Fantinel, S., additional, Farnea, E., additional, Faul, T., additional, Filliger, M., additional, Filmer, F., additional, Finck, Ch., additional, de France, G., additional, Gadea, A., additional, Gast, W., additional, Geraci, A., additional, Gerl, J., additional, Gernhäuser, R., additional, Giannatiempo, A., additional, Giaz, A., additional, Gibelin, L., additional, Givechev, A., additional, Goel, N., additional, González, V., additional, Gottardo, A., additional, Grave, X., additional, Gre¸bosz, J., additional, Griffiths, R., additional, Grint, A.N., additional, Gros, P., additional, Guevara, L., additional, Gulmini, M., additional, Görgen, A., additional, Ha, H.T.M., additional, Habermann, T., additional, Harkness, L.J., additional, Harroch, H., additional, Hauschild, K., additional, He, C., additional, Hernández-Prieto, A., additional, Hervieu, B., additional, Hess, H., additional, Hüyük, T., additional, Ince, E., additional, Isocrate, R., additional, Jaworski, G., additional, Johnson, A., additional, Jolie, J., additional, Jones, P., additional, Jonson, B., additional, Joshi, P., additional, Judson, D.S., additional, Jungclaus, A., additional, Kaci, M., additional, Karkour, N., additional, Karolak, M., additional, Kaşkaş, A., additional, Kebbiri, M., additional, Kempley, R.S., additional, Khaplanov, A., additional, Klupp, S., additional, Kogimtzis, M., additional, Kojouharov, I., additional, Korichi, A., additional, Korten, W., additional, Kröll, Th., additional, Krücken, R., additional, Kurz, N., additional, Ky, B.Y., additional, Labiche, M., additional, Lafay, X., additional, Lavergne, L., additional, Lazarus, I.H., additional, Leboutelier, S., additional, Lefebvre, F., additional, Legay, E., additional, Legeard, L., additional, Lelli, F., additional, Lenzi, S.M., additional, Leoni, S., additional, Lermitage, A., additional, Lersch, D., additional, Leske, J., additional, Letts, S.C., additional, Lhenoret, S., additional, Lieder, R.M., additional, Linget, D., additional, Ljungvall, J., additional, Lopez-Martens, A., additional, Lotodé, A., additional, Lunardi, S., additional, Maj, A., additional, van der Marel, J., additional, Mariette, Y., additional, Marginean, N., additional, Marginean, R., additional, Maron, G., additional, Mather, A.R., additional, Me¸czyński, W., additional, Mendéz, V., additional, Medina, P., additional, Melon, B., additional, Menegazzo, R., additional, Mengoni, D., additional, Merchan, E., additional, Mihailescu, L., additional, Michelagnoli, C., additional, Mierzejewski, J., additional, Milechina, L., additional, Million, B., additional, Mitev, K., additional, Molini, P., additional, Montanari, D., additional, Moon, S., additional, Morbiducci, F., additional, Moro, R., additional, Morrall, P.S., additional, Möller, O., additional, Nannini, A., additional, Napoli, D.R., additional, Nelson, L., additional, Nespolo, M., additional, Ngo, V.L., additional, Nicoletto, M., additional, Nicolini, R., additional, Le Noa, Y., additional, Nolan, P.J., additional, Norman, M., additional, Nyberg, J., additional, Obertelli, A., additional, Olariu, A., additional, Orlandi, R., additional, Oxley, D.C., additional, Özben, C., additional, Ozille, M., additional, Oziol, C., additional, Pachoud, E., additional, Palacz, M., additional, Palin, J., additional, Pancin, J., additional, Parisel, C., additional, Pariset, P., additional, Pascovici, G., additional, Peghin, R., additional, Pellegri, L., additional, Perego, A., additional, Perrier, S., additional, Petcu, M., additional, Petkov, P., additional, Petrache, C., additional, Pierre, E., additional, Pietralla, N., additional, Pietri, S., additional, Pignanelli, M., additional, Piqueras, I., additional, Podolyak, Z., additional, Le Pouhalec, P., additional, Pouthas, J., additional, Pugnére, D., additional, Pucknell, V.F.E., additional, Pullia, A., additional, Quintana, B., additional, Raine, R., additional, Rainovski, G., additional, Ramina, L., additional, Rampazzo, G., additional, La Rana, G., additional, Rebeschini, M., additional, Recchia, F., additional, Redon, N., additional, Reese, M., additional, Reiter, P., additional, Regan, P.H., additional, Riboldi, S., additional, Richer, M., additional, Rigato, M., additional, Rigby, S., additional, Ripamonti, G., additional, Robinson, A.P., additional, Robin, J., additional, Roccaz, J., additional, Ropert, J.-A., additional, Rossé, B., additional, Rossi Alvarez, C., additional, Rosso, D., additional, Rubio, B., additional, Rudolph, D., additional, Saillant, F., additional, Şahin, E., additional, Salomon, F., additional, Salsac, M.-D., additional, Salt, J., additional, Salvato, G., additional, Sampson, J., additional, Sanchis, E., additional, Santos, C., additional, Schaffner, H., additional, Schlarb, M., additional, Scraggs, D.P., additional, Seddon, D., additional, Şenyiğit, M., additional, Sigward, M.-H., additional, Simpson, G., additional, Simpson, J., additional, Slee, M., additional, Smith, J.F., additional, Sona, P., additional, Sowicki, B., additional, Spolaore, P., additional, Stahl, C., additional, Stanios, T., additional, Stefanova, E., additional, Stézowski, O., additional, Strachan, J., additional, Suliman, G., additional, Söderström, P.-A., additional, Tain, J.L., additional, Tanguy, S., additional, Tashenov, S., additional, Theisen, Ch., additional, Thornhill, J., additional, Tomasi, F., additional, Toniolo, N., additional, Touzery, R., additional, Travers, B., additional, Triossi, A., additional, Tripon, M., additional, Tun-Lanoë, K.M.M., additional, Turcato, M., additional, Unsworth, C., additional, Ur, C.A., additional, Valiente-Dobon, J.J., additional, Vandone, V., additional, Vardaci, E., additional, Venturelli, R., additional, Veronese, F., additional, Veyssiere, Ch., additional, Viscione, E., additional, Wadsworth, R., additional, Walker, P.M., additional, Warr, N., additional, Weber, C., additional, Weisshaar, D., additional, Wells, D., additional, Wieland, O., additional, Wiens, A., additional, Wittwer, G., additional, Wollersheim, H.J., additional, Zocca, F., additional, Zamfir, N.V., additional, Zie¸bliński, M., additional, and Zucchiatti, A., additional

Published

2012

98. 16+Spin-Gap Isomer inCd96

Author

Nara Singh, B. S., primary, Liu, Z., additional, Wadsworth, R., additional, Grawe, H., additional, Brock, T. S., additional, Boutachkov, P., additional, Braun, N., additional, Blazhev, A., additional, Górska, M., additional, Pietri, S., additional, Rudolph, D., additional, Domingo-Pardo, C., additional, Steer, S. J., additional, Ataç, A., additional, Bettermann, L., additional, Cáceres, L., additional, Eppinger, K., additional, Engert, T., additional, Faestermann, T., additional, Farinon, F., additional, Finke, F., additional, Geibel, K., additional, Gerl, J., additional, Gernhäuser, R., additional, Goel, N., additional, Gottardo, A., additional, Grȩbosz, J., additional, Hinke, C., additional, Hoischen, R., additional, Ilie, G., additional, Iwasaki, H., additional, Jolie, J., additional, Kaşkaş, A., additional, Kojouharov, I., additional, Krücken, R., additional, Kurz, N., additional, Merchán, E., additional, Nociforo, C., additional, Nyberg, J., additional, Pfützner, M., additional, Prochazka, A., additional, Podolyák, Zs., additional, Regan, P. H., additional, Reiter, P., additional, Rinta-Antila, S., additional, Scholl, C., additional, Schaffner, H., additional, Söderström, P.-A., additional, Warr, N., additional, Weick, H., additional, Wollersheim, H.-J., additional, Woods, P. J., additional, Nowacki, F., additional, and Sieja, K., additional

Published

2011

99. Exotic nuclear studies around and below A = 100

Author

Nara Singh, B. S., primary, Wadsworth, R., additional, Boutachkov, P., additional, Blazhev, A., additional, Liu, Z., additional, Grawe, H., additional, Brock, T. S., additional, Braun, N., additional, Go, M., additional, Pietri, S., additional, Rudolph, D., additional, Domingo-Pardo, C., additional, Steer, S. J., additional, Atac, A., additional, Bettermann, L., additional, Cáceres, L., additional, Eppinger, K., additional, Engert, T., additional, Faestermann, T., additional, Farinon, F., additional, Finke, F., additional, Geibel, K., additional, Gerl, J., additional, Gernhäuser, R., additional, Goel, N., additional, Gottardo, A., additional, Grȩbosz, J., additional, Hinke, C., additional, Hoischen, R., additional, llie, G., additional, Iwasaki, H., additional, Jolie, J., additional, Kaşkaş, A., additional, Kojouharov, I., additional, Krücken, R., additional, Kurz, N., additional, Merchánt, E., additional, Nociforo, C., additional, Nyberg, J., additional, Pfützner, M., additional, Prochazka, A., additional, Podolyák, Zs., additional, Regan, P. H, additional, Reiter, P., additional, Rinta-Antila, S., additional, Scholl, C., additional, Schaffner, H., additional, Söderström, P.-A., additional, Warr, N., additional, Weick, H., additional, Wollersheim, H.-J., additional, Woods, P. J., additional, Nowacki, F., additional, Sieja, K., additional, and Blank, Bertram, additional

Published

2011

100. A case of cutaneous Rosai-Dorfman disease (CRDD) with underlying calvarial involvement and absence of BRAFV600E mutation

Author

Kaskas, Nadine M., Kern, Malan, Johnson, Andrew, Hughes, Matthew P., Hardee, Matthew, Day, John, Gokden, Murat, Shalin, Sara C., and Gao, Ling

Published

2015