Access the full text.
Sign up today, get DeepDyve free for 14 days.
M. Kaltenbrunner, M. White, E. Głowacki, T. Sekitani, T. Someya, N. Sariciftci, S. Bauer (2012)
Ultrathin and lightweight organic solar cells with high flexibilityNature Communications, 3
R. Polson, Z. Vardeny (2004)
Random lasing in human tissuesApplied Physics Letters, 85
M. Kaltenbrunner, T. Sekitani, J. Reeder, T. Yokota, K. Kuribara, T. Tokuhara, M. Drack, R. Schwödiauer, I. Graz, S. Bauer-Gogonea, S. Bauer, T. Someya (2013)
An ultra-lightweight design for imperceptible plastic electronicsNature, 499
N. Lawandy, R. Balachandran, A. Gomes, E. Sauvain (1994)
Laser action in strongly scattering mediaNature, 368
M. White, M. Kaltenbrunner, M. Kaltenbrunner, E. Głowacki, Kateryna Gutnichenko, G. Kettlgruber, I. Graz, S. Aazou, C. Ulbricht, D. Egbe, M. Miron, Z. Major, M. Scharber, T. Sekitani, T. Someya, S. Bauer, N. Sariciftci (2013)
Ultrathin, highly flexible and stretchable PLEDsNature Photonics, 7
G. Salvatore, N. Münzenrieder, T. Kinkeldei, L. Petti, C. Zysset, Ivo Strebel, Lars Büthe, G. Tröster (2014)
Wafer-scale design of lightweight and transparent electronics that wraps around hairsNature Communications, 5
Yujie Chen, J. Herrnsdorf, B. Guilhabert, A. Kanibolotsky, A. Mackintosh, Yue Wang, R. Pethrick, E. Gu, G. Turnbull, P. Skabara, I. Samuel, N. Laurand, M. Dawson (2011)
Laser action in a surface-structured free-standing membrane based on a π-conjugated polymer-compositeOrganic Electronics, 12
Xiyun Liu, Tingshuai Li, Tao Yi, Chuanke Wang, Jin Li, Min Xu, Dengfeng Huang, Shen-ye Liu, Shaoen Jiang, Yongkun Ding (2016)
Random laser action from a natural flexible biomembrane-based deviceJournal of Modern Optics, 63
T. Zhai, Zhiyang Xu, Xiaofeng Wu, Yimeng Wang, Feifei Liu, Xinping Zhang (2016)
Ultra-thin plasmonic random lasers.Optics express, 24 1
Shu-Jang Chen, Xiaoye Zhao, Yanrong Wang, Jinwei Shi, Da-he Liu (2012)
White light emission with red-green-blue lasing action in a disordered system of nanoparticlesApplied Physics Letters, 101
Tzu‐Min Sun, Cih-Su Wang, Chi-Shiun Liao, Shih-Yao Lin, Packiyaraj Perumal, C. Chiang, Y. Chen (2015)
Stretchable Random Lasers with Tunable Coherent Loops.ACS nano, 9 12
T. Zhai, Xinping Zhang, Zhaoguang Pang, Xue-qiong Su, Hongmei Liu, Shengfei Feng, Li Wang (2011)
Random laser based on waveguided plasmonic gain channels.Nano letters, 11 10
D. Wiersma, S. Cavalieri (2001)
Light emission: A temperature-tunable random laserNature, 414
Moliria Santos, C. Dominguez, J. Schiavon, H. Barud, L. Melo, S. Ribeiro, A. Gomes, C. Araújo (2014)
Random laser action from flexible biocellulose-based deviceJournal of Applied Physics, 115
Chi Lee, Dong Kim, Xiaolin Zheng (2010)
Fabricating nanowire devices on diverse substrates by simple transfer-printing methodsProceedings of the National Academy of Sciences, 107
Suk-ho Kim, Jongwon Yoon, S. Yun, Youngkyu Hwang, Hun Jang, Heung Ko (2013)
Ultrathin Sticker‐Type ZnO Thin Film Transistors Formed by Transfer Printing via Topological Confinement of Water‐Soluble Sacrificial Polymer in Dimple StructureAdvanced Functional Materials, 23
Kunook Chung, Chul‐Ho Lee, G. Yi (2010)
Transferable GaN Layers Grown on ZnO-Coated Graphene Layers for Optoelectronic DevicesScience, 330
M. Drack, I. Graz, T. Sekitani, T. Someya, M. Kaltenbrunner, S. Bauer (2014)
An Imperceptible Plastic Electronic WrapAdvanced Materials (Deerfield Beach, Fla.), 27
R. Silva, C. Dominguez, Moliria Santos, R. Barbosa-Silva, M. Cavicchioli, Livia Christovan, L. Melo, A. Gomes, C. Araújo, S. Ribeiro (2013)
Silk fibroin biopolymer films as efficient hosts for DFB laser operationJournal of Materials Chemistry C, 1
H. Cao, Y. Zhao, S. Ho, E. Seelig, Qing Wang, R. Chang (1999)
Random laser action in semiconductor powderPhysical Review Letters, 82
D. Wiersma (2008)
The physics and applications of random lasersNature Physics, 4
Ying‐Chih Lai, Yi-Chuan Huang, Tai-Yuan Lin, Yi-Xian Wang, Chun‐Yu Chang, Yao-Hsuan Li, Tzu-Yao Lin, Bo-Wei Ye, Y. Hsieh, W. Su, Ying-Jay Yang, Yanguang Chen (2014)
Stretchable organic memory: toward learnable and digitized stretchable electronic applicationsNpg Asia Materials, 6
Quy Thanh, H. Jeong, Jinwoong Kim, J. Kevek, Y. Ahn, Soonil Lee, E. Minot, Ji-Yong Park (2012)
Transfer‐Printing of As‐Fabricated Carbon Nanotube Devices onto Various SubstratesAdvanced Materials, 24
D. Neamen (2012)
Semiconductor physics and devices : basic principles
R. Sapienza, P. García, S. Gottardo, A. Blanco, D. Wiersma, C. López (2009)
Resonance-driven random lasersCLEO/Europe - EQEC 2009 - European Conference on Lasers and Electro-Optics and the European Quantum Electronics Conference
Cih-Su Wang, C. Nieh, Tai-Yuan Lin, Y. Chen (2015)
Electrically Driven Random Laser MemoryAdvanced Functional Materials, 25
Chi Lee, Dong Kim, I. Cho, N. William, Qi Wang, Xiaolin Zheng (2012)
Peel-and-Stick: Fabricating Thin Film Solar Cell on Universal SubstratesScientific Reports, 2
Xuan Cao, Yu Cao, Chongwu Zhou (2016)
Imperceptible and Ultraflexible p-Type Transistors and Macroelectronics Based on Carbon Nanotubes.ACS nano, 10 1
Chul‐Ho Lee, Yong‐Jin Kim, Young Hong, S. Jeon, S. Bae, B. Hong, G. Yi (2011)
Flexible Inorganic Nanostructure Light‐Emitting Diodes Fabricated on Graphene FilmsAdvanced Materials, 23
Chi Lee, Dong Kim, Xiaolin Zheng (2011)
Fabrication of nanowire electronics on nonconventional substrates by water-assisted transfer printing method.Nano letters, 11 8
Random lasers have abundant inherent advantages compared to conventional laser, such as flexibility, size, cost, simple design, and mass production. It has been the hot research topic in recent decades. An integrated random laser label with transferability, flexibility, and temperature sensing is created and demonstrated in this work. The highly stretchable label‐type random laser (HSRL) can not only function stably under 100% strain with at least 500 times test but can also be easily transferred on arbitrary substrates irrespective of the material being rigid, flexible, nonplanar, or rough. In addition to features mentioned above, random laser signals can be stimulated and controlled repetitively within human body temperature. This shows great potential that the HSRL can serve as photonics modules for further advanced developments of a variety of applications covering many different fields, such as wearable systems, robotic sensors, and stretchable information communications.
Advanced Materials Technologies – Wiley
Published: Sep 1, 2016
Keywords: ; ; ;
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.