Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer

Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer

An extended model based on nonlocal polymerization-driven diffusion model is derived by introducing shrinkage process for describing photopolymerized dynamics in PQ-PMMA photopolymer. The kinetic parameters, polymerization rate and diffusion rate are experimentally determined to provide quantitative...

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Bibliographic Details
Main Authors: Wei Zepeng, Yu Dan, Li Xiaolan, Wang Yanwen, Chen Zhuang, Geng Yaohui, Lv Jiang
Format: Article
Language:English
Published: EDP Sciences 2015-01-01
Series:MATEC Web of Conferences
Subjects:
photopolymer
holographic grating
diffusion model
shrinkage
Online Access:http://dx.doi.org/10.1051/matecconf/20152502010
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spelling doaj-975158eb9e1d410c8238297b5d6a6f0d2021-02-02T07:20:52ZengEDP SciencesMATEC Web of Conferences2261-236X2015-01-01250201010.1051/matecconf/20152502010matecconf_emme2015_02010Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA PhotopolymerWei Zepeng0Yu Dan1Li Xiaolan2Wang Yanwen3Chen Zhuang4Geng Yaohui5Lv Jiang6China College of Sciences, Tianjin University of TechnologyChina College of Sciences, Tianjin University of TechnologyChina College of Sciences, Tianjin University of TechnologyChina College of Sciences, Tianjin University of TechnologyChina College of Sciences, Tianjin University of TechnologyChina College of Sciences, Tianjin University of TechnologyChina College of Sciences, Tianjin University of TechnologyAn extended model based on nonlocal polymerization-driven diffusion model is derived by introducing shrinkage process for describing photopolymerized dynamics in PQ-PMMA photopolymer. The kinetic parameters, polymerization rate and diffusion rate are experimentally determined to provide quantitative simulation. The numerical results show that the fringes at edge of grating are firstly shifted and consequently, it leads to a contrast reduction of holograms. Finally, theoretical results are experimentally checked by temporal evolution of diffraction efficiency, and the shrinkage coefficient 0.5% is approximately achieved under incident intensity 25.3mw/cm2. This work can enhance the applicability of diffusion model and contribute to the reasonable description of the grating formation in the photopolymer.http://dx.doi.org/10.1051/matecconf/20152502010photopolymerholographic gratingdiffusion modelshrinkage
collection DOAJ
language English
format Article
sources DOAJ
author Wei Zepeng
Yu Dan
Li Xiaolan
Wang Yanwen
Chen Zhuang
Geng Yaohui
Lv Jiang
spellingShingle Wei Zepeng
Yu Dan
Li Xiaolan
Wang Yanwen
Chen Zhuang
Geng Yaohui
Lv Jiang
Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer
MATEC Web of Conferences
photopolymer
holographic grating
diffusion model
shrinkage
author_facet Wei Zepeng
Yu Dan
Li Xiaolan
Wang Yanwen
Chen Zhuang
Geng Yaohui
Lv Jiang
author_sort Wei Zepeng
title Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer
title_short Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer
title_full Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer
title_fullStr Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer
title_full_unstemmed Shrinkage Simulation of Holographic Grating Using Diffusion Model in PQ-PMMA Photopolymer
title_sort shrinkage simulation of holographic grating using diffusion model in pq-pmma photopolymer
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2015-01-01
description An extended model based on nonlocal polymerization-driven diffusion model is derived by introducing shrinkage process for describing photopolymerized dynamics in PQ-PMMA photopolymer. The kinetic parameters, polymerization rate and diffusion rate are experimentally determined to provide quantitative simulation. The numerical results show that the fringes at edge of grating are firstly shifted and consequently, it leads to a contrast reduction of holograms. Finally, theoretical results are experimentally checked by temporal evolution of diffraction efficiency, and the shrinkage coefficient 0.5% is approximately achieved under incident intensity 25.3mw/cm2. This work can enhance the applicability of diffusion model and contribute to the reasonable description of the grating formation in the photopolymer.
topic photopolymer
holographic grating
diffusion model
shrinkage
url http://dx.doi.org/10.1051/matecconf/20152502010
work_keys_str_mv AT weizepeng shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
AT yudan shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
AT lixiaolan shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
AT wangyanwen shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
AT chenzhuang shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
AT gengyaohui shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
AT lvjiang shrinkagesimulationofholographicgratingusingdiffusionmodelinpqpmmaphotopolymer
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