Holographic Properties of Acrylate Photopolymer Materials with Double Monomers

Biao KANG; Huaqing LÜ; Yourong LIU; Shaoxin LI; Jihong ZHENG

doi:10.3788/gzxb20225105.0509001

Journals >Acta Photonica Sinica >Volume 51 >Issue 5 >Page 0509001 > Article

Acta Photonica Sinica
Vol. 51, Issue 5, 0509001 (2022)

Holographic Properties of Acrylate Photopolymer Materials with Double Monomers

Biao KANG^1、2, Huaqing LÜ^1、2, Yourong LIU^1、2, Shaoxin LI^1、2, and Jihong ZHENG^1、2、*

Author Affiliations

¹School of Optical-Electrical and Computer Engineering，University of Shanghai Science and Technology，Shanghai 200093，China

²Shanghai Key Lab of Modern Optical System，University of Shanghai Science and Technology，Shanghai 200093，China

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DOI: 10.3788/gzxb20225105.0509001 Cite this Article

Biao KANG, Huaqing LÜ, Yourong LIU, Shaoxin LI, Jihong ZHENG. Holographic Properties of Acrylate Photopolymer Materials with Double Monomers[J]. Acta Photonica Sinica, 2022, 51(5): 0509001 Copy Citation Text

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Fig. 1. Principle and formation process of bimolecular photopolymer grating

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Fig. 2. Holographic recording optical path

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$Relationship between diffraction efficiency and exposure time of four double monomer samples$

Fig. 3. Relationship between diffraction efficiency and exposure time of four double monomer samples

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$Variation of diffraction efficiency of different active monomers under different exposure conditions$

Fig. 4. Variation of diffraction efficiency of different active monomers under different exposure conditions

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$Variation of diffraction efficiency and transmission efficiency under different photoinitiators$

Fig. 5. Variation of diffraction efficiency and transmission efficiency under different photoinitiators

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$Diffraction efficiency of different proportions of double monomers$

Fig. 6. Diffraction efficiency of different proportions of double monomers

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Fig. 7. Reconstruction angular bandwidth of double monomer

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Fig. 8. Temperature and humidity cycle of double monomer and aged sample

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Sample	Film forming resin	TMPTA	NVP	NPG	RB
A（DPHPA）	41.48%	41.48%	15.2%	1.15%	0.7%
B（EB8301）	41.48%	41.48%	15.2%	1.15%	0.7%
C（Epikote 828）	41.48%	41.48%	15.2%	1.15%	0.7%
D（TFPMA）	41.48%	41.48%	15.2%	1.15%	0.7%

Table 1. Composition and ratio of four materials

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TMPTA and epoxy resin	Incident light intensity/μW	Transmission intensity/μW	Diffraction intensity/μW	Reflected light intensity/μW	Absorptivity	Diffraction efficiency	Refractive index modulation
Before aging	663	41.3	420	72	4.4%	91.5%	2.98×10^-3
After aging	667	63.9	435	82	0.9%	87.2%	2.82×10^-3

Table 2. Changes of photopolymer materials of double monomer system before and after aging

Biao KANG, Huaqing LÜ, Yourong LIU, Shaoxin LI, Jihong ZHENG. Holographic Properties of Acrylate Photopolymer Materials with Double Monomers[J]. Acta Photonica Sinica, 2022, 51(5): 0509001

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