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Artículos de revistas sobre el tema "Photonic time-Stretch"

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Autor: Grafiati
Publicado: 22 de junio de 2024

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1

Wang, Guoqing, Yuan Zhou, Rui Min, E. Du y Chao Wang. "Principle and Recent Development in Photonic Time-Stretch Imaging". Photonics 10, n.º 7 (13 de julio de 2023): 817. http://dx.doi.org/10.3390/photonics10070817.

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Inspiring development in optical imaging enables great applications in the science and engineering industry, especially in the medical imaging area. Photonic time-stretch imaging is one emerging innovation that attracted a wide range of attention due to its principle of one-to-one-to-one mapping among space-wavelength-time using dispersive medium both in spatial and time domains. The ultrafast imaging speed of the photonics time-stretch imaging technique achieves an ultrahigh frame rate of tens of millions of frames per second, which exceeds the traditional imaging methods in several orders of magnitudes. Additionally, regarding ultrafast optical signal processing, it can combine several other optical technologies, such as compressive sensing, nonlinear processing, and deep learning. In this paper, we review the principle and recent development of photonic time-stretch imaging and discuss the future trends.
2

Mei, Yuan, Boyu Xu, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin y Xianmin Zhang. "Harmonics analysis of the photonic time stretch system". Applied Optics 55, n.º 26 (6 de septiembre de 2016): 7222. http://dx.doi.org/10.1364/ao.55.007222.

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3

Zlokazov, E. Yu, R. S. Starikov y V. A. Nebavskiy. "Mathematical modelling of microwave photonic time-stretch system". Journal of Physics: Conference Series 737 (agosto de 2016): 012001. http://dx.doi.org/10.1088/1742-6596/737/1/012001.

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4

Zhang, Yaowen, Rongting Jin, Di Peng, Weiqiang Lyu, Zhenwei Fu, Zhiyao Zhang, Shangjian Zhang, Heping Li y Yong Liu. "Broadband Transient Waveform Digitizer Based on Photonic Time Stretch". Journal of Lightwave Technology 39, n.º 9 (1 de mayo de 2021): 2880–87. http://dx.doi.org/10.1109/jlt.2021.3061511.

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5

Saltarelli, Francesco, Vikas Kumar, Daniele Viola, Francesco Crisafi, Fabrizio Preda, Giulio Cerullo y Dario Polli. "Photonic Time-Stretch Spectroscopy for Multiplex Stimulated Raman Scattering". EPJ Web of Conferences 205 (2019): 03003. http://dx.doi.org/10.1051/epjconf/201920503003.

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Stimulated Raman scattering spectroscopy enables label-free molecular identification, but its broadband implementation is technically challenging. We experimentally demonstrate a novel approach to multiplex stimulated Raman scattering based on photonic time stretch. A telecom fiber stretches the broadband femtosecond Stokes pulse after the sample to ∼15ns, mapping its spectrum in time. The signal is sampled through a fast oscilloscope, providing single-shot spectra at 80-kHz rate. We demonstrate high sensitivity in detecting the Raman vibrational modes of various samples over the entire high-frequency C-H stretching region. Our results pave the way to high-speed broadband vibrational imaging for materials science and biophotonics.
6

Shu, Haowen, Lin Chang, Yuansheng Tao, Bitao Shen, Weiqiang Xie, Ming Jin, Andrew Netherton et al. "Microcomb-driven silicon photonic systems". Nature 605, n.º 7910 (18 de mayo de 2022): 457–63. http://dx.doi.org/10.1038/s41586-022-04579-3.

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AbstractMicrocombs have sparked a surge of applications over the past decade, ranging from optical communications to metrology1–4. Despite their diverse deployment, most microcomb-based systems rely on a large amount of bulky elements and equipment to fulfil their desired functions, which is complicated, expensive and power consuming. By contrast, foundry-based silicon photonics (SiPh) has had remarkable success in providing versatile functionality in a scalable and low-cost manner5–7, but its available chip-based light sources lack the capacity for parallelization, which limits the scope of SiPh applications. Here we combine these two technologies by using a power-efficient and operationally simple aluminium-gallium-arsenide-on-insulator microcomb source to drive complementary metal–oxide–semiconductor SiPh engines. We present two important chip-scale photonic systems for optical data transmission and microwave photonics, respectively. A microcomb-based integrated photonic data link is demonstrated, based on a pulse-amplitude four-level modulation scheme with a two-terabit-per-second aggregate rate, and a highly reconfigurable microwave photonic filter with a high level of integration is constructed using a time-stretch approach. Such synergy of a microcomb and SiPh integrated components is an essential step towards the next generation of fully integrated photonic systems.
7

Zhu, Qian, Leran Wang, Lei Yang, Hongbo Xie y Daoyin Yu. "Ultrafast photonic time-stretch imaging using an optically transparent medium". Applied Physics Express 13, n.º 10 (10 de septiembre de 2020): 102001. http://dx.doi.org/10.35848/1882-0786/abb344.

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8

Mei, Yuan, Yuxiao Xu, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin y Xianmin Zhang. "Spurious-Free Dynamic Range of the Photonic Time-Stretch System". IEEE Photonics Technology Letters 29, n.º 10 (15 de mayo de 2017): 794–97. http://dx.doi.org/10.1109/lpt.2017.2685624.

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9

Liu, Changqiao, Xiaofeng Jin, Boyu Xu, Xiangdong Jin, Xianmin Zhang, Shilie Zheng y Hao Chi. "Impact of 3rd-order dispersion on photonic time-stretch system". Optics Communications 402 (noviembre de 2017): 206–10. http://dx.doi.org/10.1016/j.optcom.2017.05.079.

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10

Xu, Yuxiao, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin y Xianmin Zhang. "On the undesired frequency chirping in photonic time-stretch systems". Optics Communications 405 (diciembre de 2017): 192–96. http://dx.doi.org/10.1016/j.optcom.2017.08.005.

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11

Yang, Lei, Hui Chen, Jun Ma, Qian Zhu, Tong Yang y Hongbo Xie. "Photonic Time-Stretch Technology with Prismatic Pulse Dispersion towards Fast Real-Time Measurements". Photonics 6, n.º 3 (9 de septiembre de 2019): 99. http://dx.doi.org/10.3390/photonics6030099.

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Photonic time-stretch (PTS) technology enables revolutionary technical breakthroughs in ultrafast electronic and optical systems. By means of employing large chromatic dispersion to map the spectrum of an ultrashort optical pulse into a stretched time-domain waveform (namely, using the dispersive Fourier transformation), PTS overcomes the fundamental speed limitations of conventional techniques. The chromatic dispersion utilized in PTS can be implemented using multiple optical prism arrays, which have the particular advantages of low loss in the extended spectrum outside of the specific telecommunication band, flexibility, and cost-effectiveness. In this article, we propose and demonstrate the PTS technology established for a pair of prisms, which works as a data acquisition approach in ultrafast digitizing, imaging, and measurement regimes.
12

Zhang, Yukang y Hao Chi. "An Optical Front-End for Wideband Transceivers Based on Photonic Time Compression and Stretch". Photonics 9, n.º 9 (15 de septiembre de 2022): 658. http://dx.doi.org/10.3390/photonics9090658.

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This study proposes an optical front-end for wideband transceivers based on photonic time compression (PTC) and photonic time stretch (PTS) techniques. The PTC and PTS systems within a transceiver generate and receive wideband RF signals, respectively, which expand the processible signal bandwidth. We present analytical models for characterizing the optical front-end based on the PTC and PTS. The design of the front-end for signal generation and reception is also discussed, in which we emphasize the bandwidth match between the PTC-based transmitter and PTS-based receiver through an appropriate dispersion configuration. We conducted experiments on PTC and PTS systems with a single channel. Further simulation results for PTC and PTS systems with multiple channels for continuous-time operation are presented. The proposed front-end based on time compression/stretch can largely improve the signal bandwidth in systems using inexpensive low-speed analogue/digital converters.
13

Gupta, Shalabh y Bahram Jalali. "Time-warp correction and calibration in photonic time-stretch analog-to-digital converter". Optics Letters 33, n.º 22 (14 de noviembre de 2008): 2674. http://dx.doi.org/10.1364/ol.33.002674.

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14

Fard, Ali M., Shalabh Gupta y Bahram Jalali. "Photonic time-stretch digitizer and its extension to real-time spectroscopy and imaging". Laser & Photonics Reviews 7, n.º 2 (15 de enero de 2013): 207–63. http://dx.doi.org/10.1002/lpor.201200015.

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15

Han, Y., O. Boyraz y B. Jalali. "Ultrawide-band photonic time-stretch a/D converter employing phase diversity". IEEE Transactions on Microwave Theory and Techniques 53, n.º 4 (abril de 2005): 1404–8. http://dx.doi.org/10.1109/tmtt.2005.845757.

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16

Szwaj, C., C. Evain, M. Le Parquier, P. Roy, L. Manceron, J. B. Brubach, M. A. Tordeux y S. Bielawski. "High sensitivity photonic time-stretch electro-optic sampling of terahertz pulses". Review of Scientific Instruments 87, n.º 10 (octubre de 2016): 103111. http://dx.doi.org/10.1063/1.4964702.

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17

Xu, Boyu, Changqiao Liu, Xiaofeng Jin, Xiangdong Jin, Xianbin Yu, Hao Chi, Shilie Zheng y Xianmin Zhang. "Frequency-dependent noise figure analysis of continuous photonic time-stretch system". Applied Optics 56, n.º 29 (9 de octubre de 2017): 8246. http://dx.doi.org/10.1364/ao.56.008246.

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18

Coppinger, F., A. S. Bhushan y B. Jalali. "Photonic time stretch and its application to analog-to-digital conversion". IEEE Transactions on Microwave Theory and Techniques 47, n.º 7 (julio de 1999): 1309–14. http://dx.doi.org/10.1109/22.775471.

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19

Xie, Xinggang, Xiaoli Yin, Sha Li, Li Li, Xiangjun Xin y Chongxiu Yu. "Photonic time-stretch analog-to-digital converter employing envelope removing technique". Optik 125, n.º 9 (mayo de 2014): 2195–98. http://dx.doi.org/10.1016/j.ijleo.2013.10.027.

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20

Jalali, B., F. Coppinger y A. S. Bhushan. "Photonic Time-stretch Offers Solution to Ultrafast Analog-to-digital Conversion". Optics and Photonics News 9, n.º 12 (1 de diciembre de 1998): 31. http://dx.doi.org/10.1364/opn.9.12.000031.

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21

Mididoddi, Chaitanya K., Fangliang Bai, Guoqing Wang, Jinchao Liu, Stuart Gibson y Chao Wang. "High-Throughput Photonic Time-Stretch Optical Coherence Tomography with Data Compression". IEEE Photonics Journal 9, n.º 4 (agosto de 2017): 1–15. http://dx.doi.org/10.1109/jphot.2017.2716179.

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22

Fuster, J. M., D. Novak, A. Nirmalathas y J. Marti. "Single-sideband modulation in photonic time-stretch analogue-to-digital conversion". Electronics Letters 37, n.º 1 (2001): 67. http://dx.doi.org/10.1049/el:20010046.

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23

Chi, Hao, Ying Chen, Yuan Mei, Xiaofeng Jin, Shilie Zheng y Xianmin Zhang. "Microwave spectrum sensing based on photonic time stretch and compressive sampling". Optics Letters 38, n.º 2 (8 de enero de 2013): 136. http://dx.doi.org/10.1364/ol.38.000136.

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24

Teng, Yun, Chong-xiu Yu, Jin-hui Yuan, Jing-xuan Chen, Cang Jin y Qian Xu. "Time-stretch analog-to-digital conversion with a photonic crystal fiber". Optoelectronics Letters 7, n.º 2 (marzo de 2011): 143–46. http://dx.doi.org/10.1007/s11801-011-0149-1.

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25

Yang, Shuna, Jian Wang, Bo Yang, Hao Chi, Jun Ou, Yanrong Zhai y Qiliang Li. "A serial digital-to-analog conversion based on photonic time-stretch technology". Optics Communications 510 (mayo de 2022): 127949. http://dx.doi.org/10.1016/j.optcom.2022.127949.

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26

Bhushan, A. S., P. V. Kelkar, B. Jalali, O. Boyraz y M. Islam. "130-GSa/s photonic analog-to-digital converter with time stretch preprocessor". IEEE Photonics Technology Letters 14, n.º 5 (mayo de 2002): 684–86. http://dx.doi.org/10.1109/68.998725.

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27

Liu, Changqiao, Xiaofeng Jin, Xiangdong Jin, Xianbin Yu, Qinggui Tan y Guoyong Wang. "Signal Frequency Chirp of Photonic Time-Stretch System Due to Nonlinear Dispersion". IEEE Photonics Technology Letters 31, n.º 6 (15 de marzo de 2019): 443–46. http://dx.doi.org/10.1109/lpt.2019.2897723.

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28

Zheng, Jian, Wei Feng y Sha Li. "Photonic time stretch preprocessor employing coherent detection in analog-to-digital converter". Optik 124, n.º 20 (octubre de 2013): 4647–50. http://dx.doi.org/10.1016/j.ijleo.2013.01.036.

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29

Yang, Bo, Qing Xu, Shuna Yang y Hao Chi. "Wideband sparse signal acquisition with ultrahigh sampling compression ratio based on continuous-time photonic time stretch and photonic compressive sampling". Applied Optics 61, n.º 6 (10 de febrero de 2022): 1344. http://dx.doi.org/10.1364/ao.450386.

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30

Qian Aquan, 钱阿权, 邹卫文 Zou Weiwen, 吴龟灵 Wu Guiling y 陈建平 Chen Jianping. "Design and Implementation of Multi-Channel Photonic Time-Stretch Analog-to-Digital Converter". Chinese Journal of Lasers 42, n.º 5 (2015): 0505001. http://dx.doi.org/10.3788/cjl201542.0505001.

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31

Li, Sha y Chong-Xiu Yu. "Ultrahigh sampling rate photonic time stretch analog-to-digital converter employing phase modulation". Optik 124, n.º 20 (octubre de 2013): 4539–43. http://dx.doi.org/10.1016/j.ijleo.2013.02.011.

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32

Li, Bo, Shuqin Lou y José Azaña. "Implementation of the photonic time-stretch concept using an incoherent pulsed light source". Applied Optics 54, n.º 10 (25 de marzo de 2015): 2757. http://dx.doi.org/10.1364/ao.54.002757.

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33

Mididoddi, Chaitanya K. y Chao Wang. "Adaptive non-uniform photonic time stretch for blind RF signal detection with compressed time-bandwidth product". Optics Communications 396 (agosto de 2017): 221–27. http://dx.doi.org/10.1016/j.optcom.2017.03.052.

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34

Fard, Ali, Brandon Buckley y Bahram Jalali. "Spectral Efficiency Improvement in Photonic Time-Stretch Analog-to-Digital Converter via Polarization Multiplexing". IEEE Photonics Technology Letters 23, n.º 14 (julio de 2011): 947–49. http://dx.doi.org/10.1109/lpt.2011.2142414.

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35

Fard, Ali M., Peter T. S. DeVore, Daniel R. Solli y Bahram Jalali. "Impact of Optical Nonlinearity on Performance of Photonic Time-Stretch Analog-to-Digital Converter". Journal of Lightwave Technology 29, n.º 13 (julio de 2011): 2025–30. http://dx.doi.org/10.1109/jlt.2011.2157304.

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36

Fard, Ali, Shalabh Gupta y Bahram Jalali. "Digital broadband linearization technique and its application to photonic time-stretch analog-to-digital converter". Optics Letters 36, n.º 7 (18 de marzo de 2011): 1077. http://dx.doi.org/10.1364/ol.36.001077.

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37

Stigwall, Johan y Sheila Galt. "Signal Reconstruction by Phase Retrieval and Optical Backpropagation in Phase-Diverse Photonic Time-Stretch Systems". Journal of Lightwave Technology 25, n.º 10 (octubre de 2007): 3017–27. http://dx.doi.org/10.1109/jlt.2007.905893.

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38

Xia Nan, 夏楠, 陈颖 Chen Ying, 陈向宁 Chen Xiangning, 邹卫文 Zou Weiwen, 吴龟灵 Wu Guiling y 陈建平 Chen Jianping. "Impact of Nonlinearity Effect on the Performance of Photonic Time-Stretch Analog-to-Digital Converter System". Acta Optica Sinica 34, n.º 6 (2014): 0606002. http://dx.doi.org/10.3788/aos201434.0606002.

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39

Peng, Di, Zhiyao Zhang, Zhen Zeng, Lingjie Zhang, Yanjia Lyu, Yong Liu y Kang Xie. "Single-shot photonic time-stretch digitizer using a dissipative soliton-based passively mode-locked fiber laser". Optics Express 26, n.º 6 (5 de marzo de 2018): 6519. http://dx.doi.org/10.1364/oe.26.006519.

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40

Gee, Caroline M., George Sefler, Peter T. S. DeVore y George C. Valley. "Spurious‐Free dynamic range of a high‐resolution photonic time‐stretch analog‐to‐digital converter system". Microwave and Optical Technology Letters 54, n.º 11 (24 de agosto de 2012): 2558–63. http://dx.doi.org/10.1002/mop.27114.

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41

Sefler, George A. y George C. Valley. "Mitigation of Group-Delay-Ripple Distortions for Use of Chirped Fiber-Bragg Gratings in Photonic Time-Stretch ADCs". Journal of Lightwave Technology 31, n.º 7 (abril de 2013): 1093–100. http://dx.doi.org/10.1109/jlt.2013.2243404.

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42

Qian, Na, Weiwen Zou, Siteng Zhang y Jianping Chen. "Signal-to-noise ratio improvement of photonic time-stretch coherent radar enabling high-sensitivity ultrabroad W-band operation". Optics Letters 43, n.º 23 (29 de noviembre de 2018): 5869. http://dx.doi.org/10.1364/ol.43.005869.

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43

Peng, Di, Zhiyao Zhang, Yangxue Ma, Yali Zhang, Shangjian Zhang y Yong Liu. "Optimized Single-Shot Photonic Time-Stretch Digitizer Using Complementary Parallel Single-Sideband Modulation Architecture and Digital Signal Processing". IEEE Photonics Journal 9, n.º 3 (junio de 2017): 1–14. http://dx.doi.org/10.1109/jphot.2017.2694442.

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44

Chen, Ying, Hao Chi, Tao Jin, Shilie Zheng, Xiaofeng Jin y Xianmin Zhang. "Sub-Nyquist Sampled Analog-to-Digital Conversion Based on Photonic Time Stretch and Compressive Sensing With Optical Random Mixing". Journal of Lightwave Technology 31, n.º 21 (noviembre de 2013): 3395–401. http://dx.doi.org/10.1109/jlt.2013.2282088.

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45

Li, Caiyun, Jiangyong He, Yange Liu, Yang Yue, Luhe Zhang, Longfei Zhu, Mengjie Zhou, Congcong Liu, Kaiyan Zhu y Zhi Wang. "Comparing Performance of Deep Convolution Networks in Reconstructing Soliton Molecules Dynamics from Real-Time Spectral Interference". Photonics 8, n.º 2 (13 de febrero de 2021): 51. http://dx.doi.org/10.3390/photonics8020051.

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Deep neural networks have enabled the reconstruction of optical soliton molecules with more complex structures using the real-time spectral interferences obtained by photonic time-stretch dispersive Fourier transformation (TS-DFT) technology. In this paper, we propose to use three kinds of deep convolution networks (DCNs), including VGG, ResNets, and DenseNets, for revealing internal dynamics evolution of soliton molecules based on the real-time spectral interferences. When analyzing soliton molecules with equidistant composite structures, all three models are effective. The DenseNets with layers of 48 perform the best for extracting the dynamic information of complex five-soliton molecules from TS-DFT data. The mean Pearson correlation coefficient (MPCC) between the predicted results and the real results is about 0.9975. Further, the ResNets in which the MPCC achieves 0.9906 also has the better ability of phase extraction than VGG which the MPCC is about 0.9739. The general applicability is demonstrated for extracting internal information from complex soliton molecule structures with high accuracy. The presented DCNs-based techniques can be employed to explore undiscovered mechanisms underlying the distribution and evolution of large numbers of solitons in dissipative systems in experimental research.
46

Jiang, Xingyu, Shuaijian Yang y Leni Zhong. "(Invited) Stretchable and Biodegradable Sensors Based on Liquid Metal-Polymer Composites Encapsulated in Microfluidics". ECS Meeting Abstracts MA2023-02, n.º 63 (22 de diciembre de 2023): 2975. http://dx.doi.org/10.1149/ma2023-02632975mtgabs.

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Photolithography and related advances have made microfluidics, microelectromechanical systems and related systems accessible to many biomecial labs. These systems have found uses in biochemical assays, pharmaceutical screening and many fields of applications. Conductive inks made from lipid metal-polymer composites (MPC) can be encapsulated within elastomer-based microfluidic channels that serve as conducting wires that are flexible, stretchable and completely biodegradable. Such flexible devices have allow the introduction of electrical and photonic signals seamlessly into living tissues. These properties can dramatically expand the capability of stretch electronic devices as biomedical sensors, as well as sensors for electrophysiology, tissue engineering, regenerative medicine and gene therapy. MPC-based epidermal liquid metal-based electronics, such as blood oxygen sensors and sweat detection devices, allow real-time health monitoring. I will also discuss the idea of an “electronic blood vessel” that integrates sensing with regeneration. Eventually, these sensors can also harness the chemical energy within bodies to comprise self-power devices.
47

Peng, Di, Zhiyao Zhang, Yangxue Ma, Yali Zhang, Shangjian Zhang y Yong Liu. "Broadband linearization in photonic time-stretch analog-to-digital converters employing an asymmetrical dual-parallel Mach-Zehnder modulator and a balanced detector". Optics Express 24, n.º 11 (18 de mayo de 2016): 11546. http://dx.doi.org/10.1364/oe.24.011546.

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48

Yin, Tenghao, Danming Zhong, Junjie Liu, Xiangjiang Liu, Honghui Yu y Shaoxing Qu. "Stretch tuning of the Debye ring for 2D photonic crystals on a dielectric elastomer membrane". Soft Matter 14, n.º 7 (2018): 1120–29. http://dx.doi.org/10.1039/c7sm02322g.

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49

Ugo, Cataldi y Buergi Thomas. "Plasmonic coupling induced by growing processes of metal nanoparticles in wrinkled structures and driven by mechanical strain applied to a polidimethisiloxisilane template". Photonics Letters of Poland 9, n.º 2 (1 de julio de 2017): 45. http://dx.doi.org/10.4302/plp.v9i2.702.

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We report the mechanical control of plasmonic coupling between gold nanoparticles (GNPs) coated onto a large area wrinkled surface of an elastomeric template. Self-assembly and bottom-up procedures, were used to fabricate the sample and to increase the size of GNPs by exploiting the reduction of HAuCl4 with hydroxylamine. The elastic properties of template, the increase of nanostructure size joined with the particular grating configuration of the surface have been exploited to trigger and handle the coupling processes between the nanoparticles. Full Text: PDF ReferencesG. Mie, "Beiträge zur Optik trüber Medien, speziell kolloidaler Metallösungen", Ann. Phys. 25, 377 (1908) CrossRef U. Kreibig and M. Vollmer, Optical properties of metal cluster, Berlin 1995 CrossRef S. A. Maier, Plasmonics: Fundamentals and Applications, Springer, New York, 2007 CrossRef L. A. Lane, X. Qian, and S. Nie, "SERS Nanoparticles in Medicine: From Label-Free Detection to Spectroscopic Tagging", Chem. 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Asghari, Hossein y Max Hushahn. "Multi-Probe Photonic Time-Stretch: Design and Applications". SSRN Electronic Journal, 2023. http://dx.doi.org/10.2139/ssrn.4345360.

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