Fabrication of 3D polymeric photonic arrays and related applications

Yadav, A.1; Kaushik, A.2; Mishra, Y.K.3; Agrawal, V.4; Ahmadivand, A.5; Maliutina, K.6; Liu, Y.7; Ouyang, Z.8; Dong, W.1; Cheng, G.J.9

2020

10.1016/j.mtchem.2019.100208

Materials Today Chemistry   影响因子和分区

24685194

This review article describes the state-of-art methodologies, mainly self-assembly routes, which are in practice to fabricate photonic crystals (PCs) for advanced applications. The self-assembly of colloidal building blocks is an effective, affordable, and tunable approach to fabricate varieties of photonic materials of desired shapes and surface areas. Because of easy fabrication and controlled performance factors, PCs emerged as a potential platform for designing and developing optical devices with desired features such as photonic bandgap, high reflectance/transmittance, low loss, and lasing in the visible range of wavelengths. To develop next-generation optoelectronics and optical system, significant efforts are being made to explore novel and cost-effective fabrication methods to design and develop 3D-PCs platform, which is covered in this mini-review. The challenges, potential alternatives, and prospects of self-assembled 3D PCs are also discussed in this review.
© 2019 Elsevier Ltd

Colloidal photonic crystals Lasing Spontaneous emission Self-assembly Plasmonic sensors

EI ; ESCI ; SCI

英语

其他

Science and Technology Innovation as a Whole Plan Projects of Shaanxi Province[2017AHB065] ; National Natural Science Foundation of China[51873165]

Materials Science

Materials Science, Multidisciplinary

WOS:000537732800001

Elsevier Ltd

20194907790261

Colloids ; Cost effectiveness ; Optical systems ; Photonic crystals ; Plasmonics ; Self assembly ; Spontaneous emission

Electromagnetic Waves:711 ; Optical Devices and Systems:741.3 ; Colloid Chemistry:801.3 ; Industrial Economics:911.2 ; Materials Science:951

EV Compendex

1.Hubei Key Laboratory of Advanced Textiles Materials & Applications, Wuhan Textiles University, Wuhan; 430200, China
2.Department of Natural Sciences, Division of Sciences, Art, & Mathematics, Florida Polytechnic University, Lakeland, United States
3.Mads Clausen Institute, NanoSYD, University of Southern Denmark, Alsion 2, Sonderborg; 6400, Denmark
4.School of Physics, Southeast University Nanjing, China
5.Department of Electrical & Computer Engineering, Rice University, 6100 Main St, Houston, United States
6.College of Chemistry and Environmental Engineering, Shenzhen University, China
7.Department of Electrical and Electronic Engineering, Southern University of Science and Technology, Shenzhen; 518055, China
8.THz Technical Research Center of Shenzhen University, Coll. Electronic Sci. & Technol., Shenzhen Univ., Shenzhen; 518060, China
9.School of Industrial Engineering, Purdue University, 315 N. Grant St, West Lafayette; IN; 47907, United States

Yadav, A.,Kaushik, A.,Mishra, Y.K.,et al. Fabrication of 3D polymeric photonic arrays and related applications[J]. Materials Today Chemistry,2020,15.

Yadav, A..,Kaushik, A..,Mishra, Y.K..,Agrawal, V..,Ahmadivand, A..,...&Cheng, G.J..(2020).Fabrication of 3D polymeric photonic arrays and related applications.Materials Today Chemistry,15.

Yadav, A.,et al."Fabrication of 3D polymeric photonic arrays and related applications".Materials Today Chemistry 15(2020).