Analyzation of photopolymer materials shrunken influence for thick hologram gratings

Zhenzhen Li; Xue Xiao; Wei Chen; Guoguo Kang; Yong Huang; Xiaodi Tan

doi:10.1117/12.2235317

Analyzation of photopolymer materials shrunken influence for thick hologram gratings

Zhenzhen Li, Xue Xiao, Wei Chen, Guoguo Kang, Yong Huang, Xiaodi Tan

School of Optics and Photonics

Beijing Institute of Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Citation (Scopus)

Abstract

The photopolymer materials are good media to record thick hologram gratings, because photopolymer materials have high resolution, low cost, simple process technology and so on. According to coupled wave theory for thick hologram gratings, we know that the same object beam can be reconstructed if the same reference beam is used to retrieve a thick hologram grating. However, the shrinkage always occurs in the photopolymer materials because of environment temperature, humidity, vibration etc. For instance, the same object beam cannot be reconstructed even the same reference beam to be used. In this paper, we will analysis the shrinkage influence of photopolymer materials for thick hologram gratings. We divide the photopolymer materials into several geometry layers, and analysis the reconstructed characteristics separately basing on coupled wave theory of Kogelnik. Through gradually continuous changing the angle between gratings and the border (we call it slant angle), we can build the geometry model of gratings bending caused by shrinkage of materials. We calculate wave complex amplitude diffracted from every layer, and superpose them to compute the total diffraction efficiency. We simulate above methods to obtain the curve of diffraction efficiency with reconstruction wavelength by using Matlab software. Comparing the simulated results with the experiments results, we can deduce the probable situation of thick hologram gratings bending after photopolymer materials shrink.

Original language	English
Title of host publication	Polymer Optics and Molded Glass Optics
Subtitle of host publication	Design, Fabrication, and Materials 2016
Editors	David H. Krevor, Alan Symmons, William S. Beich, Michael P. Schaub
Publisher	SPIE
ISBN (Electronic)	9781510602892
DOIs	https://doi.org/10.1117/12.2235317
Publication status	Published - 2016
Event	Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016 - San Diego, United States Duration: 29 Aug 2016 → …

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	9949
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016
Country/Territory	United States
City	San Diego
Period	29/08/16 → …

Keywords

Bend
Complex amplitude
Coupled wave theory
Diffraction efficiency
Layers
Photopolymer materials
Reconstruction
Shrinkage
Slant angle
Thick hologram gratings

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10.1117/12.2235317

Cite this

Li, Z., Xiao, X., Chen, W., Kang, G., Huang, Y., & Tan, X. (2016). Analyzation of photopolymer materials shrunken influence for thick hologram gratings. In D. H. Krevor, A. Symmons, W. S. Beich, & M. P. Schaub (Eds.), Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016 Article 99490L (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9949). SPIE. https://doi.org/10.1117/12.2235317

Li, Zhenzhen ; Xiao, Xue ; Chen, Wei et al. / Analyzation of photopolymer materials shrunken influence for thick hologram gratings. Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016. editor / David H. Krevor ; Alan Symmons ; William S. Beich ; Michael P. Schaub. SPIE, 2016. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{83c0dbfe47b74cb99fc9bc7df2457e61,

title = "Analyzation of photopolymer materials shrunken influence for thick hologram gratings",

abstract = "The photopolymer materials are good media to record thick hologram gratings, because photopolymer materials have high resolution, low cost, simple process technology and so on. According to coupled wave theory for thick hologram gratings, we know that the same object beam can be reconstructed if the same reference beam is used to retrieve a thick hologram grating. However, the shrinkage always occurs in the photopolymer materials because of environment temperature, humidity, vibration etc. For instance, the same object beam cannot be reconstructed even the same reference beam to be used. In this paper, we will analysis the shrinkage influence of photopolymer materials for thick hologram gratings. We divide the photopolymer materials into several geometry layers, and analysis the reconstructed characteristics separately basing on coupled wave theory of Kogelnik. Through gradually continuous changing the angle between gratings and the border (we call it slant angle), we can build the geometry model of gratings bending caused by shrinkage of materials. We calculate wave complex amplitude diffracted from every layer, and superpose them to compute the total diffraction efficiency. We simulate above methods to obtain the curve of diffraction efficiency with reconstruction wavelength by using Matlab software. Comparing the simulated results with the experiments results, we can deduce the probable situation of thick hologram gratings bending after photopolymer materials shrink.",

keywords = "Bend, Complex amplitude, Coupled wave theory, Diffraction efficiency, Layers, Photopolymer materials, Reconstruction, Shrinkage, Slant angle, Thick hologram gratings",

author = "Zhenzhen Li and Xue Xiao and Wei Chen and Guoguo Kang and Yong Huang and Xiaodi Tan",

note = "Publisher Copyright: {\textcopyright} 2016 SPIE.; Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016 ; Conference date: 29-08-2016",

year = "2016",

doi = "10.1117/12.2235317",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Krevor, {David H.} and Alan Symmons and Beich, {William S.} and Schaub, {Michael P.}",

booktitle = "Polymer Optics and Molded Glass Optics",

address = "United States",

}

Li, Z, Xiao, X, Chen, W, Kang, G , Huang, Y & Tan, X 2016, Analyzation of photopolymer materials shrunken influence for thick hologram gratings. in DH Krevor, A Symmons, WS Beich & MP Schaub (eds), Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016., 99490L, Proceedings of SPIE - The International Society for Optical Engineering, vol. 9949, SPIE, Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016, San Diego, United States, 29/08/16. https://doi.org/10.1117/12.2235317

Analyzation of photopolymer materials shrunken influence for thick hologram gratings. / Li, Zhenzhen; Xiao, Xue; Chen, Wei et al.
Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016. ed. / David H. Krevor; Alan Symmons; William S. Beich; Michael P. Schaub. SPIE, 2016. 99490L (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9949).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Analyzation of photopolymer materials shrunken influence for thick hologram gratings

AU - Li, Zhenzhen

AU - Xiao, Xue

AU - Chen, Wei

AU - Kang, Guoguo

AU - Huang, Yong

AU - Tan, Xiaodi

PY - 2016

Y1 - 2016

N2 - The photopolymer materials are good media to record thick hologram gratings, because photopolymer materials have high resolution, low cost, simple process technology and so on. According to coupled wave theory for thick hologram gratings, we know that the same object beam can be reconstructed if the same reference beam is used to retrieve a thick hologram grating. However, the shrinkage always occurs in the photopolymer materials because of environment temperature, humidity, vibration etc. For instance, the same object beam cannot be reconstructed even the same reference beam to be used. In this paper, we will analysis the shrinkage influence of photopolymer materials for thick hologram gratings. We divide the photopolymer materials into several geometry layers, and analysis the reconstructed characteristics separately basing on coupled wave theory of Kogelnik. Through gradually continuous changing the angle between gratings and the border (we call it slant angle), we can build the geometry model of gratings bending caused by shrinkage of materials. We calculate wave complex amplitude diffracted from every layer, and superpose them to compute the total diffraction efficiency. We simulate above methods to obtain the curve of diffraction efficiency with reconstruction wavelength by using Matlab software. Comparing the simulated results with the experiments results, we can deduce the probable situation of thick hologram gratings bending after photopolymer materials shrink.

AB - The photopolymer materials are good media to record thick hologram gratings, because photopolymer materials have high resolution, low cost, simple process technology and so on. According to coupled wave theory for thick hologram gratings, we know that the same object beam can be reconstructed if the same reference beam is used to retrieve a thick hologram grating. However, the shrinkage always occurs in the photopolymer materials because of environment temperature, humidity, vibration etc. For instance, the same object beam cannot be reconstructed even the same reference beam to be used. In this paper, we will analysis the shrinkage influence of photopolymer materials for thick hologram gratings. We divide the photopolymer materials into several geometry layers, and analysis the reconstructed characteristics separately basing on coupled wave theory of Kogelnik. Through gradually continuous changing the angle between gratings and the border (we call it slant angle), we can build the geometry model of gratings bending caused by shrinkage of materials. We calculate wave complex amplitude diffracted from every layer, and superpose them to compute the total diffraction efficiency. We simulate above methods to obtain the curve of diffraction efficiency with reconstruction wavelength by using Matlab software. Comparing the simulated results with the experiments results, we can deduce the probable situation of thick hologram gratings bending after photopolymer materials shrink.

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KW - Complex amplitude

KW - Coupled wave theory

KW - Diffraction efficiency

KW - Layers

KW - Photopolymer materials

KW - Reconstruction

KW - Shrinkage

KW - Slant angle

KW - Thick hologram gratings

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DO - 10.1117/12.2235317

M3 - Conference contribution

AN - SCOPUS:85008462611

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Polymer Optics and Molded Glass Optics

A2 - Krevor, David H.

A2 - Symmons, Alan

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A2 - Schaub, Michael P.

PB - SPIE

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Li Z, Xiao X, Chen W, Kang G , Huang Y, Tan X. Analyzation of photopolymer materials shrunken influence for thick hologram gratings. In Krevor DH, Symmons A, Beich WS, Schaub MP, editors, Polymer Optics and Molded Glass Optics: Design, Fabrication, and Materials 2016. SPIE. 2016. 99490L. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2235317

Analyzation of photopolymer materials shrunken influence for thick hologram gratings

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