Your search keyword '"Pu, Y.-K."' showing total 24 results

1. Measurement of the surface charging of a plasma actuator using surface DBD

Author

Hong, D., Rabat, H., Pu, Y.-K., and Leroy, A.

Published

2013

2. Diagnostic of ultrafast temporal plasma evolution in high-power microwave discharge.

Author

Chang, C., Wu, C., Pu, Y. K., Zhu, M., Zhang, X., and Verboncoeur, J.

Subjects

HIGH-frequency discharges, MICROWAVE plasmas, SPECTROMETERS, PLASMA dynamics, ELECTRON density

Abstract

For the most advanced multi-frame camera in the world, the shortest response time between two frames is no shorter than 1.5 ns. Thus, there is no effective way to diagnose the ultrafast sub-nanosecond dynamic of a microwave-driven plasma discharge in a single pulse. Different-length multi-sub-beam optical fibers, together with a spectrometer and an EMICCD camera, are proposed and designed to detect the nanosecond discharge spectra in a single pulse, like a real-time multi-frame spectral camera. This novel method could realize a time interval between two consecutive frames shorter than 0.1 ns by a length difference of 2 cm for sub-fibers, achieving the measurement of ultrafast plasma dynamics. Temporal evolution of electron density as well as energy of electrons and ions during nanosecond microwave discharge is further studied by de-convolving the Stark broadening and thermal Doppler broadening and by calculating the ratio of emission coefficients. [ABSTRACT FROM AUTHOR]

Published

2017

3. Temporal and spatial evolution of nanosecond microwave-driven plasma

Author

Chang, C., primary, Chen, X. Q., additional, Zhu, M., additional, and Pu, Y. K., additional

Published

2018

4. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

Adamovich, I., Baalrud, S.D., Bogaerts, A., Bruggeman, P.J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U. (Ute), Eden, J.G., Favia, P. (Pietro), Graves, D.B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I.D., Kortshagen, U., Kushner, M.J., Mason, N.J., Mazouffre, S., Mededovic Thagard, S., Metelmann, H.-R., Mizuno, A., Moreau, E., Murphy, A.B., Niemira, B.A., Oehrlein, G.S., Petrović, Z.L. (Zoran), Pitchford, L.C., Pu, Y.-K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M.M., Sanden, M.C.M. van de, Vardelle, A., Adamovich, I., Baalrud, S.D., Bogaerts, A., Bruggeman, P.J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U. (Ute), Eden, J.G., Favia, P. (Pietro), Graves, D.B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I.D., Kortshagen, U., Kushner, M.J., Mason, N.J., Mazouffre, S., Mededovic Thagard, S., Metelmann, H.-R., Mizuno, A., Moreau, E., Murphy, A.B., Niemira, B.A., Oehrlein, G.S., Petrović, Z.L. (Zoran), Pitchford, L.C., Pu, Y.-K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M.M., Sanden, M.C.M. van de, and Vardelle, A.

Abstract

Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges.

Published

2017

5. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

Adamovich, I, primary, Baalrud, S D, additional, Bogaerts, A, additional, Bruggeman, P J, additional, Cappelli, M, additional, Colombo, V, additional, Czarnetzki, U, additional, Ebert, U, additional, Eden, J G, additional, Favia, P, additional, Graves, D B, additional, Hamaguchi, S, additional, Hieftje, G, additional, Hori, M, additional, Kaganovich, I D, additional, Kortshagen, U, additional, Kushner, M J, additional, Mason, N J, additional, Mazouffre, S, additional, Thagard, S Mededovic, additional, Metelmann, H-R, additional, Mizuno, A, additional, Moreau, E, additional, Murphy, A B, additional, Niemira, B A, additional, Oehrlein, G S, additional, Petrovic, Z Lj, additional, Pitchford, L C, additional, Pu, Y-K, additional, Rauf, S, additional, Sakai, O, additional, Samukawa, S, additional, Starikovskaia, S, additional, Tennyson, J, additional, Terashima, K, additional, Turner, M M, additional, van de Sanden, M C M, additional, and Vardelle, A, additional

Published

2017

6. Temporal and spatial evolution of nanosecond microwave-driven plasma.

Author

Zhu, M., Chang, C., Chen, X. Q., and Pu, Y. K.

Subjects

MICROWAVE plasmas, SPATIOTEMPORAL processes, PLASMA spectroscopy, SPECTROMETERS, PLASMA flow, MATHEMATICAL models

Abstract

In this paper, a method for simultaneously acquiring the temporal and spatial evolution of characteristic plasma spectra in a single microwave pulse is proposed and studied. By using multi-sub-beam fiber bundles coupled with a spectrometer and EMICCD (Electron-multiplying intensified charge-coupled device), the spatial distribution and time evolution of characteristic spectra of desorbed gases at the dielectric/vacuum interface during nanosecond microwave-driven plasma discharge are observed. Arrays of small align tubes punctured with metal walls of feed horn are filled with separate fibers of matched sizes and equal lengths. The output ends of fibers arranged in a single longitudinal column are connected to the entrance slit of a spectrometer, where the optical spectrum inputs to a high-speed EMICCD, to detect the rapid-varying time and space spectra of nanosecond giga-watt microwave discharges. The evolution of spectral clusters of N2 (C-B), N2+ (B-X), and the hydrogen atoms is discovered and monitored. The whole duration of light emission is much longer than the microwave pulse, and the intensities of ion N2+ (B-X) spectra increase after microwave pulses with rise times of 25–50 ns. The brightness distribution of plasma spectra in different space is observed and approximately consistent with the simulated E-field distribution. [ABSTRACT FROM AUTHOR]

Published

2018

7. Simulating the Influence of Obstacles on Accelerating Dust and Gas Flames

Author

Skjold, Trygve, Pu, Y. K., Arntzen, Bjørn Johan, Hansen, Olav R., Storvik, Idar E., Taraldset, Ole Jacob, and Eckhoff, Rolf Kristian

Abstract

Presented at: Twentieth International Colloquium on the Dynamics of Explosions and Reactive Systems (ICDERS), Montreal, 31 July – 5 August 2005

Published

2005

8. Measurement of the electron density in atmospheric-pressure low-temperature argon discharges by line-ratio method of optical emission spectroscopy

Author

Zhu, X M, Pu, Y K, Balcon, Nicolas, Boswell, Roderick, Zhu, X M, Pu, Y K, Balcon, Nicolas, and Boswell, Roderick

Abstract

A new collisional-radiative model for atmospheric-pressure low-temperature argon discharges is proposed, which illustrates the significant effect of electron density on the excited atom population distribution. This makes it possible to determine the electron density from the intensity ratio of emission lines of excited atoms. Results of this new method in several types of atmospheric-pressure discharges are found to be in agreement with those of the Stark broadening method and the electric model over a wide electron density range 1011-1016 cm-3.

Published

2009

9. Argon ion velocity distributions in a helicon discharge measured by laser induced fluorescence

Author

Luggenhölscher, D, primary, Celik, Y, additional, Pu, Y K, additional, and Czarnetzki, U, additional

Published

2010

10. Measurement of the electron density in atmospheric-pressure low-temperature argon discharges by line-ratio method of optical emission spectroscopy

Author

Zhu, X M, primary, Pu, Y K, additional, Balcon, N, additional, and Boswell, R, additional

Published

2009

11. Reconstruction of ion energy distribution function in a capacitive rf discharge

Author

Chen, W. C., primary, Zhu, X. M., additional, Zhang, S., additional, and Pu, Y. K., additional

Published

2009

12. Candidate mode for electron thermal energy transport in multi-keV plasmas

Author

Coppi, B., primary, Migliuolo, S., additional, and Pu, Y-K., additional

Published

1990

13. Plasma instability in ECR heated ion sources

Author

Pu, Y.-K., primary and Halverson, W., additional

Published

1990

14. Electron cyclotron resonance ion source frequency scaling and radial confinement in a quadrupole magnetic field

Author

Pu, Y. K., primary, Halverson, W., additional, Petty, C., additional, Smatlak, D., additional, and Torti, R., additional

Published

1990

15. The dependence of GaN growth rate on electron temperature in an ECR plasma

Author

Pu, Y. K., Ren, Y. F., Yang, S. Z., Dywer, D., Zhang, X. G., and Jia, X. J.

Published

2000

16. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

Adamovich, I, Baalrud, S D, Bogaerts, A, Bruggeman, P J, Cappelli, M, Colombo, V, Czarnetzki, U, Ebert, U, Eden, J G, Favia, P, Graves, D B, Hamaguchi, S, Hieftje, G, Hori, M, Kaganovich, I D, Kortshagen, U, Kushner, M J, Mason, N. J., Mazouffre, S, Thagard, S Mededovic, Metelmann, H-R, Mizuno, A, Moreau, E, Murphy, A B, Niemira, B A, Oehrlein, G S, Petrovic, Z Lj, Pitchford, L C, Pu, Y-K, Rauf, S, Sakai, O, Samukawa, S, Starikovskaia, S, Tennyson, J, Terashima, K, Turner, M M, van de Sanden, M C M, Vardelle, A, Adamovich, I, Baalrud, S D, Bogaerts, A, Bruggeman, P J, Cappelli, M, Colombo, V, Czarnetzki, U, Ebert, U, Eden, J G, Favia, P, Graves, D B, Hamaguchi, S, Hieftje, G, Hori, M, Kaganovich, I D, Kortshagen, U, Kushner, M J, Mason, N. J., Mazouffre, S, Thagard, S Mededovic, Metelmann, H-R, Mizuno, A, Moreau, E, Murphy, A B, Niemira, B A, Oehrlein, G S, Petrovic, Z Lj, Pitchford, L C, Pu, Y-K, Rauf, S, Sakai, O, Samukawa, S, Starikovskaia, S, Tennyson, J, Terashima, K, Turner, M M, van de Sanden, M C M, and Vardelle, A

Abstract

Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges.

17. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

Adamovich, I, Baalrud, S D, Bogaerts, A, Bruggeman, P J, Cappelli, M, Colombo, V, Czarnetzki, U, Ebert, U, Eden, J G, Favia, P, Graves, D B, Hamaguchi, S, Hieftje, G, Hori, M, Kaganovich, I D, Kortshagen, U, Kushner, M J, Mason, N. J., Mazouffre, S, Thagard, S Mededovic, Metelmann, H-R, Mizuno, A, Moreau, E, Murphy, A B, Niemira, B A, Oehrlein, G S, Petrovic, Z Lj, Pitchford, L C, Pu, Y-K, Rauf, S, Sakai, O, Samukawa, S, Starikovskaia, S, Tennyson, J, Terashima, K, Turner, M M, van de Sanden, M C M, Vardelle, A, Adamovich, I, Baalrud, S D, Bogaerts, A, Bruggeman, P J, Cappelli, M, Colombo, V, Czarnetzki, U, Ebert, U, Eden, J G, Favia, P, Graves, D B, Hamaguchi, S, Hieftje, G, Hori, M, Kaganovich, I D, Kortshagen, U, Kushner, M J, Mason, N. J., Mazouffre, S, Thagard, S Mededovic, Metelmann, H-R, Mizuno, A, Moreau, E, Murphy, A B, Niemira, B A, Oehrlein, G S, Petrovic, Z Lj, Pitchford, L C, Pu, Y-K, Rauf, S, Sakai, O, Samukawa, S, Starikovskaia, S, Tennyson, J, Terashima, K, Turner, M M, van de Sanden, M C M, and Vardelle, A

Abstract

Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges.

18. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

Adamovich, I., Baalrud, S. D., Bogaerts, A., Bruggeman, P. J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U., Eden, J. G., Favia, P., Graves, D. B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I. D., Kortshagen, U., Kushner, M. J., Mason, N. J., Mazouffre, S., Thagard, S. Mededovic, Metelmann, H. R., Mizuno, A., Moreau, E., Murphy, A. B., Niemira, B. A., Oehrlein, G. S., Petrovic, Z. Lj, Pitchford, L. C., Pu, Y. K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M. M., Van De Sanden, M. C.M., Vardelle, A., Adamovich, I., Baalrud, S. D., Bogaerts, A., Bruggeman, P. J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U., Eden, J. G., Favia, P., Graves, D. B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I. D., Kortshagen, U., Kushner, M. J., Mason, N. J., Mazouffre, S., Thagard, S. Mededovic, Metelmann, H. R., Mizuno, A., Moreau, E., Murphy, A. B., Niemira, B. A., Oehrlein, G. S., Petrovic, Z. Lj, Pitchford, L. C., Pu, Y. K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M. M., Van De Sanden, M. C.M., and Vardelle, A.

Abstract

Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges., I Adamovich et al 2017 J. Phys. D: Appl. Phys. 50 323001

19. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

Adamovich, I., Baalrud, S. D., Bogaerts, A., Bruggeman, P. J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U., Eden, J. G., Favia, P., Graves, D. B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I. D., Kortshagen, U., Kushner, M. J., Mason, N. J., Mazouffre, S., Thagard, S. Mededovic, Metelmann, H. R., Mizuno, A., Moreau, E., Murphy, A. B., Niemira, B. A., Oehrlein, G. S., Petrovic, Z. Lj, Pitchford, L. C., Pu, Y. K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M. M., Van De Sanden, M. C.M., Vardelle, A., Adamovich, I., Baalrud, S. D., Bogaerts, A., Bruggeman, P. J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U., Eden, J. G., Favia, P., Graves, D. B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I. D., Kortshagen, U., Kushner, M. J., Mason, N. J., Mazouffre, S., Thagard, S. Mededovic, Metelmann, H. R., Mizuno, A., Moreau, E., Murphy, A. B., Niemira, B. A., Oehrlein, G. S., Petrovic, Z. Lj, Pitchford, L. C., Pu, Y. K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M. M., Van De Sanden, M. C.M., and Vardelle, A.

Abstract

I Adamovich et al 2017 J. Phys. D: Appl. Phys. 50 323001, Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges.

20. GYROTRON-DRIVEN ECR ION SOURCE SCALING, DESIGN, AND EXPERIMENTS

Author

HALVERSON, W., primary, PU, Y. K., additional, BROMBERG, L., additional, COHN, D., additional, PETTY, C., additional, POST, R., additional, SMATLAK, D., additional, TORTI, R., additional, and WANG, L., additional

Published

1989

21. Combined vacuum ultraviolet and optical emission analysis of an inductively coupled plasma

Author

Pu, Y.-K., primary, Guo, Z.-G., additional, and Kang, Z.-D., additional

22. Combined vacuum ultraviolet and optical emission analysis of an inductively coupled plasma.

Author

Pu, Y.-K., Guo, Z.-G., and Kang, Z.-D.

Published

2001

23. The 2017 Plasma Roadmap: Low temperature plasma science and technology

Author

M.C.M. van de Sanden, Vittorio Colombo, S. Mededovic Thagard, Brendan A. Niemira, Nigel J. Mason, Hans-Robert Metelmann, Mark A. Cappelli, Seiji Samukawa, David B. Graves, Leanne Pitchford, Pietro Favia, Osamu Sakai, Annemie Bogaerts, Satoshi Hamaguchi, Uwe Czarnetzki, Igor Kaganovich, Armelle Vardelle, Gary M. Hieftje, James Gary Eden, Jonathan Tennyson, Shahid Rauf, Uwe Kortshagen, Gottlieb S. Oehrlein, Igor Adamovich, Svetlana Starikovskaia, Anthony B. Murphy, Eric Moreau, Ute Ebert, Scott D. Baalrud, Mark J. Kushner, Stéphane Mazouffre, Masaru Hori, Kazuo Terashima, A. Mizuno, Peter Bruggeman, Miles M. Turner, Yi Kang Pu, Z. Lj. Petrović, Institut de Combustion, Aérothermique, Réactivité et Environnement (ICARE), Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Institut des Sciences de l'Ingénierie et des Systèmes (INSIS), Laboratoire de Physique des Plasmas (LPP), Université Paris-Sud - Paris 11 (UP11)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École polytechnique (X)-Sorbonne Université (SU)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Department of Physics and Astronomy [UCL London], University College of London [London] (UCL), Axe 2 : procédés plasmas et lasers (SPCTS-AXE2), Science des Procédés Céramiques et de Traitements de Surface (SPCTS), Institut des Procédés Appliqués aux Matériaux (IPAM), Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Ecole Nationale Supérieure de Céramique Industrielle (ENSCI)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université de Limoges (UNILIM)-Institut des Procédés Appliqués aux Matériaux (IPAM), Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Ecole Nationale Supérieure de Céramique Industrielle (ENSCI)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université de Limoges (UNILIM), Adamovich, I., Baalrud, S.D., Bogaerts, A., Bruggeman, P.J., Cappelli, M., Colombo, V., Czarnetzki, U., Ebert, U., Eden, J.G., Favia, P., Graves, D.B., Hamaguchi, S., Hieftje, G., Hori, M., Kaganovich, I.D., Kortshagen, U., Kushner, M.J., Mason, N.J., Mazouffre, S., Thagard, S. Mededovic, Metelmann, H.-R., Mizuno, A., Moreau, E., Murphy, A.B., Niemira, B.A., Oehrlein, G.S., Petrovic, Z Lj, Pitchford, L.C., Pu, Y.-K., Rauf, S., Sakai, O., Samukawa, S., Starikovskaia, S., Tennyson, J., Terashima, K., Turner, M.M., Van De Sanden, M.C.M., Vardelle, A., Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Institut des Sciences de l'Ingénierie et des Systèmes (INSIS - CNRS), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École polytechnique (X)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Université de Limoges (UNILIM)-Ecole Nationale Supérieure de Céramique Industrielle (ENSCI)-Institut des Procédés Appliqués aux Matériaux (IPAM), Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université de Limoges (UNILIM)-Ecole Nationale Supérieure de Céramique Industrielle (ENSCI)-Institut des Procédés Appliqués aux Matériaux (IPAM), and Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)

Subjects

010302 applied physics, Acoustics and Ultrasonics, Physics, Electronic, Optical and Magnetic Material, Low temperature plasma, Nanotechnology, Plasma, Condensed Matter Physic, Condensed Matter Physics, Acoustics and Ultrasonic, 01 natural sciences, Field (computer science), 010305 fluids & plasmas, Electronic, Optical and Magnetic Materials, Surfaces, Coatings and Films, Chemistry, Mathematics::Probability, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], 0103 physical sciences, Systems engineering, low-temperature plasma, roadmap, Science, technology and society, plasma

Abstract

I Adamovich et al 2017 J. Phys. D: Appl. Phys. 50 323001, Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges.

Published

2017

24. Cancer survival in Incheon, Republic of Korea, 1997-2001.

Author

Woo ZH, Hong YC, Kim WC, and Pu YK

Subjects

Adolescent, Adult, Aged, Child, Child, Preschool, Female, Follow-Up Studies, Humans, Infant, Infant, Newborn, Male, Middle Aged, Registries, Republic of Korea, Time Factors, Neoplasms mortality

Abstract

The Incheon cancer registry was established in 1997. Cancer is not a notifiable disease, hence registration of cases is done by active methods. The registry contributed survival data for 42 cancer sites or types registered during 1997-2001. The follow-up information has been obtained predominantly by passive methods, with median follow-up ranging between 1-44 months for various cancers. The proportion with histologically verified diagnosis for different cancers ranged between 16-100%; death certificates only (DCOs) comprised 0-51%; 49-100% of total registered cases were included for the survival analysis. The top-ranking cancers on 5-year age-standardized relative survival rates were testis (98%), thyroid (90%), ureter (87%), adrenal gland (86%), nonmelanoma skin (83%), corpus uteri (82%), Hodgkin lymphoma (81%), breast and cervix (74%). Five-year relative survival by age group showed a decreasing trend with increasing age groups for cancers of the stomach, small intestine, colon, gall bladder, larynx, lung, breast, cervix and ovary, and was fluctuating for other cancers.

Published

2011