Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces

Kazumi Serizawa; Hiroaki Onuma; Hiromi Kikuchi; Masaki Kitagaki; Itaru Yamashita; Ai Suzuki; Riadh Sahnoun; Michihisa Koyama; Hideyuki Tsuboi; Nozomu Hatakeyama; Akira Endou; Hiromitsu Takaba; Carlos A. Del Carpio; Momoji Kubo; Hiroshi Kajiyama; Akira Miyamoto

doi:10.1143/JJAP.48.04C145

Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces

Kazumi Serizawa, Hiroaki Onuma, Hiromi Kikuchi, Masaki Kitagaki, Itaru Yamashita, Ai Suzuki, Riadh Sahnoun, Michihisa Koyama, Hideyuki Tsuboi, Nozomu Hatakeyama, Akira Endou, Hiromitsu Takaba, Carlos A. Del Carpio, Momoji Kubo, Hiroshi Kajiyama, Akira Miyamoto

Research output: Contribution to journal › Article › peer-review

Abstract

High ion induced secondary electron emission (IISEE) coefficient (γ) MgO protecting layers are required in order to decrease the firing voltage of plasma display panels (PDPs). Theoretical calculation of γ for MgO surfaces provides an effective way to design better protecting layers. Here, we have developed a novel γ value estimation method based on an ultra accelerated quantum chemical molecular dynamics simulation considering the collision effect of N^e+ into a flat MgO(100) surface. Compared with experimentally obtained results, our estimated γ values are only marginally different. Our study shows that γ is primarily influenced by impact sites and N^e+ acceleration voltage. To interpret the behavior of γ in terms of these two variables, we analyzed the electronic structure of the MgO surface during the collision of Ne⁺. Our analyses show that the work function depends on impact sites and N^e+ acceleration voltage since N^e+ interacts with the surface. Our newly developed methodology enabled γ estimation from quantum chemical instances alone, considering the effect of Ne⁺ collision onto the MgO surface.

Original language	English
Article number	04C145
Journal	Japanese journal of applied physics
Volume	48
Issue number	4 PART 2
DOIs	https://doi.org/10.1143/JJAP.48.04C145
Publication status	Published - Apr 2009

All Science Journal Classification (ASJC) codes

Engineering(all)
Physics and Astronomy(all)

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Serizawa, K., Onuma, H., Kikuchi, H., Kitagaki, M., Yamashita, I., Suzuki, A., Sahnoun, R., Koyama, M., Tsuboi, H., Hatakeyama, N., Endou, A., Takaba, H., Del Carpio, C. A., Kubo, M., Kajiyama, H., & Miyamoto, A. (2009). Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces. Japanese journal of applied physics, 48(4 PART 2), Article 04C145. https://doi.org/10.1143/JJAP.48.04C145

Serizawa, K, Onuma, H, Kikuchi, H, Kitagaki, M, Yamashita, I, Suzuki, A, Sahnoun, R, Koyama, M, Tsuboi, H, Hatakeyama, N, Endou, A, Takaba, H, Del Carpio, CA, Kubo, M, Kajiyama, H & Miyamoto, A 2009, 'Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces', Japanese journal of applied physics, vol. 48, no. 4 PART 2, 04C145. https://doi.org/10.1143/JJAP.48.04C145

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title = "Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces",

abstract = "High ion induced secondary electron emission (IISEE) coefficient (γ) MgO protecting layers are required in order to decrease the firing voltage of plasma display panels (PDPs). Theoretical calculation of γ for MgO surfaces provides an effective way to design better protecting layers. Here, we have developed a novel γ value estimation method based on an ultra accelerated quantum chemical molecular dynamics simulation considering the collision effect of Ne+ into a flat MgO(100) surface. Compared with experimentally obtained results, our estimated γ values are only marginally different. Our study shows that γ is primarily influenced by impact sites and Ne+ acceleration voltage. To interpret the behavior of γ in terms of these two variables, we analyzed the electronic structure of the MgO surface during the collision of Ne+. Our analyses show that the work function depends on impact sites and Ne+ acceleration voltage since Ne+ interacts with the surface. Our newly developed methodology enabled γ estimation from quantum chemical instances alone, considering the effect of Ne+ collision onto the MgO surface.",

author = "Kazumi Serizawa and Hiroaki Onuma and Hiromi Kikuchi and Masaki Kitagaki and Itaru Yamashita and Ai Suzuki and Riadh Sahnoun and Michihisa Koyama and Hideyuki Tsuboi and Nozomu Hatakeyama and Akira Endou and Hiromitsu Takaba and {Del Carpio}, {Carlos A.} and Momoji Kubo and Hiroshi Kajiyama and Akira Miyamoto",

year = "2009",

month = apr,

doi = "10.1143/JJAP.48.04C145",

language = "English",

volume = "48",

journal = "Japanese journal of applied physics",

issn = "0021-4922",

publisher = "The Japan Society of Applied Physics",

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T1 - Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces

AU - Serizawa, Kazumi

AU - Onuma, Hiroaki

AU - Kikuchi, Hiromi

AU - Kitagaki, Masaki

AU - Yamashita, Itaru

AU - Suzuki, Ai

AU - Sahnoun, Riadh

AU - Koyama, Michihisa

AU - Tsuboi, Hideyuki

AU - Hatakeyama, Nozomu

AU - Endou, Akira

AU - Takaba, Hiromitsu

AU - Del Carpio, Carlos A.

AU - Kubo, Momoji

AU - Kajiyama, Hiroshi

AU - Miyamoto, Akira

PY - 2009/4

Y1 - 2009/4

N2 - High ion induced secondary electron emission (IISEE) coefficient (γ) MgO protecting layers are required in order to decrease the firing voltage of plasma display panels (PDPs). Theoretical calculation of γ for MgO surfaces provides an effective way to design better protecting layers. Here, we have developed a novel γ value estimation method based on an ultra accelerated quantum chemical molecular dynamics simulation considering the collision effect of Ne+ into a flat MgO(100) surface. Compared with experimentally obtained results, our estimated γ values are only marginally different. Our study shows that γ is primarily influenced by impact sites and Ne+ acceleration voltage. To interpret the behavior of γ in terms of these two variables, we analyzed the electronic structure of the MgO surface during the collision of Ne+. Our analyses show that the work function depends on impact sites and Ne+ acceleration voltage since Ne+ interacts with the surface. Our newly developed methodology enabled γ estimation from quantum chemical instances alone, considering the effect of Ne+ collision onto the MgO surface.

AB - High ion induced secondary electron emission (IISEE) coefficient (γ) MgO protecting layers are required in order to decrease the firing voltage of plasma display panels (PDPs). Theoretical calculation of γ for MgO surfaces provides an effective way to design better protecting layers. Here, we have developed a novel γ value estimation method based on an ultra accelerated quantum chemical molecular dynamics simulation considering the collision effect of Ne+ into a flat MgO(100) surface. Compared with experimentally obtained results, our estimated γ values are only marginally different. Our study shows that γ is primarily influenced by impact sites and Ne+ acceleration voltage. To interpret the behavior of γ in terms of these two variables, we analyzed the electronic structure of the MgO surface during the collision of Ne+. Our analyses show that the work function depends on impact sites and Ne+ acceleration voltage since Ne+ interacts with the surface. Our newly developed methodology enabled γ estimation from quantum chemical instances alone, considering the effect of Ne+ collision onto the MgO surface.

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Novel method based on quantum chemistry for calculation of ion induced secondary electron emission coefficient of MgO surfaces

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