Your search keyword '"J.F. Donegan"' showing total 6 results

1. SEMICONDUCTOR MATERIALS | Large Gap II–VI Semiconductors

Author

J.F. Donegan

Subjects

Semiconductor, Materials science, business.industry, Semiconductor materials, Optoelectronics, business

Published

2005

2. List of contributors

Author

R. Accomo, N. Achtziger, S.J.A. Adams, I. Akasaki, J.P. Albert, H. Amano, R. André, A. Antonelli, M. Asif Khan, R.L. Aulombard, R.F. Austin, G. Balestrino, R. Baltramiejūnas, F. Bechstedt, N. Bécourt, L. Bergman, J. Bernholc, D. Bertho, CM. Bertoni, S. Billat, M. Boćkowski, C. Bodin, C. Bodin-Deshayes, E.B. Boiko, P. Boring, A. Bouhelal, G. Bratina, K.F. Brennan, P.R. Briddon, O. Briot, I. Broser, A. Bsiesy, E. Bucher, A. Burchard, G. Cantwell, C.H. Carter, T. Castro, B.C. Cavenett, D.J. Chadi, K.M. Chen, X. Chen, H. Cheng, W.J. Choyke, N.E. Christensen, J. Cibert, R. Cingolani, T. Cloitre, P.I. Cohen, A.T. Collins, H.L. Cotal, A. Cricenti, M. Dabbicco, L.S. Dang, R.F. Davis, M. Deicher, J.M. DePuydt, B. Dischler, V.A. Dmitriev, J.F. Donegan, J.P. Doran, J.J. Dubowski, L. Eckey, J.A. Edmond, A.L. Efros, R.J. Egan, F. Engelbrecht, W. Evstropov, M. Fanciulli, R.D. Feldman, A.C. Felici, M. Ferrara, L. Ferrari, D.K. Ferry, G. Feuillet, M. Fiedler, F. Finocchi, R. Fischer, G. Fishman, A. Franciosi, Ch. Fricke, S.I. Frolov, D. Fuchs, G. Galli, S.V. Gaponenko, F. Gaspard, V.I. Gavrilenko, V. Gavryushin, W. Gebhardt, I.N. Germanenko, J. Geurts, K.P. Geyzers, B. Gil, W. Gladfelter, G. Gleitsman, E.O. Göbel, C. Godet, O. Goede, I. Gorczyca, V.P. Gribkovskii, I. Grzegory, H.-E. Gumlich, R.L. Gunshor, A.L. Gurskii, J. Gutowski, F. Gygi, M.A. Haase, C Haberstroh, W.C. Harsch, I. Hauksson, S. Hayashi, J. Hegarty, W. Heimbrodt, K. Heime, V. Heine, R. Heitz, R. Helbig, B. Henderson, F. Henneberger, R. Hérino, J. Hermans, M. Heuken, A. Hoffmann, H. Hoffmann, N. Hoffmann, H. Hofsäss, T.P. Humphreys, R.W. Hunt, S. Iarlori, S. Iida, K. Ikoma, J.P. Itie, K. Jacobs, S.G. Jahn, J.M. Jancu, C. Jaussaud, T. Jentzsch, R.L. Johnson, R. Jones, C. Jouanin, P.H. Jouneau, J. Jun, V. Jungnickel, D. Juodžbalis, S.A. Kajihara, J. Kanicki, S. Karmann, H. Katayama-Yoshida, Y. Kawakami, A. Kazlauskas, A. Kean, M.R.H. Khan, R.D. King-Smith, H. Kinto, U. Kißmann, A. Klimakow, N.I. Klyui, N. Koide, P. Koidl, H.-S. Kong, H.S. Kong, Th. König, J. Kono, V.K. Kononenko, M. Kotaki, C. Kreß, T. Krings, St. Krukowski, V. Kubertavicius, G.H. Kudlek, W. Kuhn, K. Kunc, Y. Kuroda, J.N. Kuznia, K.W. Kwak, G. Labrunie, D.B. Laks, W.R.L. Lambrecht, S. Lankes, V. Yu. Lebed, T. Lei, S. Leibenzeder, M. Lepore, T. Licht, M. Ligeon, I. Yu. Linkov, E. Litwin-Staszewska, S. Logothetidis, G. Luce, E.V. Lutsenko, M. Ch. Lux-Steiner, F. Madéore, R. Magerle, H.-E. Mahnke, K. Maier, I.E. Malinovskii, K. Manabe, M. Marinelli, B.G. Markey, A. Markwitz, T. Marshall, H. Mathieu, H. Matsunami, J.O. McCaldin, T.C. McGill, S.W.S. McKeever, J. Meier, I. Mihalcescu, E. Milani, A.I. Mitcovets, T. Mitsuyu, N. Miura, R.J. Molnar, E. Molva, M. Morohashi, Ya.V. Morozenko, T.D. Moustakas, A. Mujica, G. Mula, F. Muller, W. Müller-Sebert, A. Muñoz, A. Mura, A. Naumov, R.J. Needs, R.J. Nemanich, R. Nicolini, A.V Nurmikko, K.P. O'Donnell, T. Oguchi, K. Ohkawa, S. Okamoto, N. Okazaki, H. Okumura, M.A. Osman, J.W. Palmour, E.C. Paloura, M. Palummo, A. Paoletti, A.M. Papon, P. Paroli, M. Parrinello, G. Pensl, E. Pereira, P. Perlin, J. Petalas, W. Pfeiffer, M.C. Phillips, F.G Pikus, I. Pinter, M. Pirzer, U. Pohl, U.W. Pohl, H.M. Polatoglou, A. Polian, R. Polini, B.E. Ponga, J.L. Ponthenier, S. Porowski, J.F. Prins, K.A. Prior, J. Puls, J. Qiu, A. Qteish, G. Raciukaitis, L. Reining, T. Reisinger, M. Restle, M. Righini, P. Rodríguez-Hernández, S.J. Rolfe, R. Romestain, VD. Ryzhikov, B. Sailer, D. Sander, L. Santos, T. Sasaki, M. Sawada, G. Scamarcio, M.A. Scarselli, M. Schadt, A. Schneider, J. Schneider, A. Schöner, A. Schülzgen, S. Selci, M. Shinohara, J. Simpson, L. Sorba, B. Spellmeyer, R.P. Stanley, H. Stanzl, R.A. Stein, H. Stewart, I. Suemune, G. Sulzer, T. Suski, W. Suttrop, J.F. Swenberg, M.R. Taghizadeh, S. Takeyama, T.L. Tansley, A. Tebano, P. Thurian, E. Tosatti, C. Trager-Cowan, N. Troullier, I. Tschentscher, N. Tsuboi, A. Tsujimura, K. Tsukioka, P.A. Tupenevich, K.F. Turner, H. Uchiki, M. Uhrmacher, B. Ullrich, D. Uttamchandani, C.G. Van de Walle, J. van der Weide, J.M. Van Hove, D. Vanderbilt, L. Vanzetti, D. Vasileska, J.C. Vial, H.P. Wagner, U. Wahl, H. Waldmann, CT. Walker, E.G. Wang, M.W. Wang, S.Y. Wang, Y. Wang, V. Weinhold, T. Wiehert, C. Wild, W. Witthuhn, H. Wolf, K. Wolf, M. Wörz, G.P. Yablonskii, M. Yagi, S. Yamaga, M. Yamanaka, F. Yang, S. Yoshii, A. Yoshikawa, X. Yu, W. Zeitz, and L.G. Zimin

Published

1993

3. Resonance tuning of two-photon absorption microcavities for wavelength-selective pulse monitoring.

Author

T. Krug, W.H. Guo, J. O'Dowd, M. Lynch, A.L. Bradley, J.F. Donegan, P.J. Maguire, L.P. Barry, and H. Folliot

Abstract

We show the potential use of a single photodetector for multichannel pulse monitoring. Two-photon absorption in a microcavity structure is used as the nonlinear optical technique for pulse monitoring. Angle tuning of the device allows the resonance to be tuned. For the device studied here that is optimized for 2-ps pulses, a possible tuning range of 55 nm is shown. [ABSTRACT FROM PUBLISHER]

Published

2006

4. GaN resonant cavity light-emitting diodes for plastic optical fiber applications.

Author

A.J. Shaw, A.L. Bradley, J.F. Donegan, and J.G. Lunney

Abstract

The optical designs of resonant GaN light-emitting diodes (LEDs) have been determined for maximum extraction efficiency into typical plastic optical fiber of numerical aperture 0.5. An optimum extraction efficiency of 3.9% can be achieved for a practical resonant cavity LED (RCLED), taking account of current growth and processing considerations. The optimized device is a metal-active layer distributed Bragg reflector construction. Constructive interference effects from the top metal mirror are found to play the dominant role in efficiency enhancement. The extraction efficiency of an optimized resonant single-mirror LED is found to be 3.3%, indicating a small compromise in performance compared with the more complex RCLED structure. [ABSTRACT FROM PUBLISHER]

Published

2004

5. High-sensitivity two-photon absorption microcavity autocorrelator.

Author

T. Krug, M. Lynch, A.L. Bradley, J.F. Donegan, L.P. Barry, H. Folliot, J.S. Roberts, and G. Hill

Abstract

A GaAs-AlAs microcavity device has been used as a photodetector in an autocorrelator for measuring the temporal pulsewidth of 1.5-μm optical pulses. Enhancement of the two-photon absorption photocurrent due to the microcavity structure results in an autocorrelation (average power times peak power) sensitivity of 9.3×10-4 (mW)2, which represents two orders of magnitude improvement when compared with conventional autocorrelators. [ABSTRACT FROM PUBLISHER]

Published

2004

6. Biological applications of cadmium telluride semiconductor quantum dots

Author

Le Cigne, A., Sukhanova, A., Nabiev, I., Université de Reims Champagne-Ardenne (URCA), Laboratoire de Recherche en Nanosciences - EA 4682 (LRN), Université de Reims Champagne-Ardenne (URCA)-SFR CAP Santé (Champagne-Ardenne Picardie Santé), Université de Reims Champagne-Ardenne (URCA)-Université de Picardie Jules Verne (UPJV)-Université de Reims Champagne-Ardenne (URCA)-Université de Picardie Jules Verne (UPJV)-SFR Condorcet, Université de Reims Champagne-Ardenne (URCA)-Université de Picardie Jules Verne (UPJV)-Centre National de la Recherche Scientifique (CNRS)-Université de Reims Champagne-Ardenne (URCA)-Université de Picardie Jules Verne (UPJV)-Centre National de la Recherche Scientifique (CNRS), and J.F. Donegan, Yu. Rakovich

Subjects

[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, ComputingMilieux_MISCELLANEOUS, [SDV.MHEP]Life Sciences [q-bio]/Human health and pathology

Abstract

International audience

Published

2013