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研究生: 葉庭瑋
Yeh, Ting-Wei
論文名稱: 新穎奈米雷射之開發與應用
Developments and Applications of Novel Nano-laser
指導教授: 李亞儒
Lee, Ya-Ju
學位類別: 博士
Doctor
系所名稱: 光電工程研究所
Graduate Institute of Electro-Optical Engineering
論文出版年: 2020
畢業學年度: 108
語文別: 英文
論文頁數: 116
中文關鍵詞: 隨機雷射閥值可調式應變感測器石墨烯量子點垂直共振腔面射型雷射
英文關鍵詞: Random Laser, Tunable Threshold, Strain Sensor, Graphene Quantum Dot, Vertical Cavity Surface Emitting Laser
DOI URL: http://doi.org/10.6345/NTNU202000341
論文種類: 學術論文
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  • 近年來,隨著基礎科學的研究與發展,帶動了科學及技術的進步,雷射技術也得以迅速的發展,是由於雷射光束具有發散度極小、亮度(功率)很高、單色性好、相干性好等光學特性,因此在許多方面獲得了廣泛的應用,在工業上的雷射割切、加工、掃描、雷射雷達、雷射干涉儀,或是醫學上應用在外科手術、止血、去除色斑和修正視力,是邁向人類提高生活品質不可或缺的重要利器。而且雷射的單色性及極短脈波等,也成為發掘物質新特性的有利工具,在物理、化學、生物醫學等方面的貢獻可謂日益重大,所以新雷射的技術開發也是重大的挑戰。

    傳統雷射需要由兩面反射鏡組成共振腔,使增益介質在共振腔中累積足夠的光子,當達到居量反轉時輸出雷射光,所以通常體積大、製作不易且成本高,且光的散射會不利於雷射光的產生,因為光散射會造成損耗,而散射越強損耗就越大。反之,對於隨機雷射來說,光散射為產生隨機雷射的重要因素。利用隨機排列的散射介質來形成類似共振腔的封閉散射路徑,激發光則藉由這些封閉迴路產生多重散射。一旦平衡了系統中的淨增益和總損耗,可以在幾個方向上觀察到隨機激光發射。隨機雷射製成簡單、成本低且體積小,因此適合應用在許多領域上。像是遠程傳感器、雷射成像、醫療檢測、穿戴式感測器、顯示器或照明等等。另外我們也開發垂直共振腔面射型雷射,由於其表面法線發射、靈活的封裝能力和良好的光束質量,因此在光電技術和工業中被廣泛採用。此外,可以通過設計光學增益材料的能隙和面射型雷射腔內的諧振頻率來實現光譜發射的可調性和雷射模態選擇性。垂直腔面發射激光器是一種獨特的光源,可提供廣泛的應用,例如3D傳感、高速數據通信和雷射顯示器等等。本論文依照各個章節不同的研究主題和使用方法將摘要進行分類,其分類如下:

    1. 曲率調控之隨機雷射
    由於沒有明確的共振腔,因此限制了隨機雷射的應用,因為隨機雷射主要取決於由散射介質引起的多重光散射產生的封閉迴路,從而增加了控制難度。為了有效地調節隨機雷射,在本文中,使用水熱法成長氧化鋅奈米柱組成的無序散射體,並使用羅丹明 6G(Rhodamin 6G)作為增益介質,透過Nd:YAG脈衝雷射激發來產生隨機雷射(random laser)。光子的傳輸平均自由路徑(mean free path, MFP)可以通過彎曲下方的聚對苯二甲酸乙二醇酯(PET)柔性基板來調節曲率,從而創建可在閥值上下操作的獨特光源。此外,我們首次通過簡單的機械彎曲,將開發的曲率可調控隨機雷射用於體內生物成像,與無產生隨機雷射時的情況相比,具有更低的散斑噪聲,這對於研究快速移動的生理現象(例如老鼠耳朵皮膚中的血流模式)。曲率可調控隨機雷射的實驗可以預期成為開發基於無序的光電元件提供一條新途徑。本篇論文研究成果已投稿於Nanoscale (10.1039/c8nr09153f)。

    2. 光學應變感測隨機雷射
    本研究利用閥值可調式隨機雷射來製作高靈敏度可撓曲應變感測器,透過將隨機雷射元件成長於聚酰亞胺(PI)柔性基板上,利用氧化鋅奈米柱組成的無序散射體,激發增益介質羅丹明 6G(Rhodamin 6G)產生隨機雷射。通過在柔性基板上施加應力,使基板彎曲來演示光譜發射的可重複性和可逆調整性,這使我們能夠在低於或高於雷射閥值的情況下激發隨機雷射。此外,我們的隨機雷射在彎曲應變為 40% 的情況下,可作為穩定耐用的光學應變器,其應變係數約為 37.7  5.4,藉由低溫簡單製成的方式製作光學檢測的應變感測器,可媲美傳統的電應變感測器。這項研究證實了隨機雷射光學應變感測器可以用於各個管路、橋梁等監控,也可製作成穿戴式感測器,在這些領域中,電錶受到限制並且光學量測被認為是更好的替代方案。本篇論文研究成果已投稿於APL Materials (10.1063/1.5099316)。

    3. 石墨烯量子點垂直共振腔面射型雷射
    石墨烯量子點(GQDs)是一種新穎光學增益材料,其優異的溶液特性可用於製作高效率元件成為新光源。迄今為止,只有極少數關於GQDs產生雷射的研究。在本論文中,我們是第一個成功地製作出室溫光激發石墨烯量子點綠光面射型雷射的團隊。由Ta2O5 / SiO2兩種高折射係數差異的介電質材料做週期性堆疊成長,並設計製作布拉格反射鏡(Distributed Bragg Reflector, DBR),同時提供GQDs在光譜上的寬截止區,且在紫外光區域也具有高穿透率。藉由本實驗清楚地證明了GQDs能作為一種實用、成本低廉且高量子轉換效率的光學增益材料,展現GQD-VCSEL在寬色域雷射顯示器和投影式影像的潛在應用邁出的重要一步。本篇論文研究成果已投稿於ACS photonics (10.1021/acsphotonics.9b00976)。

    In recent years, with the research and development of basic science, which has promoted the progress of science and technology, laser technology has also been developed rapidly. The laser beam has some good optical characteristics such as a very small divergence, high brightness (power), good monochromaticity, coherence light and so on. So laser have been widely used in many aspects, such as industrial laser cutting, processing, scanning, laser radar, laser interferometer, or medical application in surgery, hemostasis, removal of stains and correction of vision are important and indispensable tools for improving the quality of life of human beings. In addition, the monochromaticity of lasers and extremely short pulse waves have also become useful tools for discovering new properties of matter. Contributions in physics, chemistry, biomedicine, etc. can be described as increasingly important, so the development of new laser technology is also a major and eternal challenge.
    The traditional laser requires a two-sided reflector to form a resonant cavity, so that the gain medium accumulates enough photons in the resonant cavity, and laser light output when it reached the population inversion. Therefore, it is usually bulky, difficult to manufacture and costly. Conversely, for a random laser, it is important to generate a random factor in the laser light scattering. A randomly arranged scattering medium is used to form a closed scattering path similar to a resonant cavity, and excitation light generates multiple scattering through these closed loops. Once equilibrated the net gain of the system and the total losses, random laser emission can be observed in several directions. Random lasers are simple, low cost, and small, making them suitable for many applications. Things like remote sensors, laser imaging, medical inspections, wearable sensors, displays or lighting, and more. In addition, we have also developed vertical cavity surface emitting lasers, which are widely used in optoelectronic technology and industry due to their surface normal emission, flexible packaging capabilities, and good beam quality. In addition, the tunability of spectral emission and laser mode selectivity can be achieved by designing the energy gap of the optical gain material and the resonance frequency in the surface-emitting laser cavity. Vertical cavity surface emitting lasers are a unique light source that can provide a wide range of applications, such as 3D sensing, high-speed data communications, and laser displays. This paper categorizes abstracts according to different research topics and methods of use in each chapter. The classification is as follows:

    1. A Curvature-Tunable Random Laser
    The application of random lasers has been restricted due to the absence of a well-defined resonant cavity, as the lasing action mainly depends on multiple light scattering induced by intrinsic disorders of the laser medium to establish the required optical feedback that hence increases the difficulty to efficiently tune and modulate random lasing emissions. This study investigated whether the transport mean free path of emitted photons within disordered scatterers composed of ZnO nanowires is tunable by a curvature bending applied to the flexible polyethylene terephthalate (PET) substrate underneath, thereby creating a unique light source that can be operated above and below the lasing threshold for desirable spectral emissions. For the first time, the developed curvature-tunable random laser is implemented for in vivo biological imaging with much lower speckle noise compared to the non-lasing situation through simple mechanical bending, which is of great potential for studying fast-moving physiological phenomenon such as blood flow patterns in a mouse ear skin. It is expected that the experimental demonstration of the curvature-tunable random laser can provide a new route to develop disorder-based optoelectronic devices. The research results of this paper have been submitted to Nanoscale (10.1039 / c8nr09153f).
    2. A Strain-Gauge Random Laser
    We describe a random laser that uses the ZnO nanorods (NRs) randomly orientated on a flexible polyimide (PI) substrate as disorderedly optical scatterers to stimulate coherent random lasing actions. Repeatable and reversible tuning of spectral emission is demonstrated by exerting a bending strain on the PI substrate, which enables us to activate the random laser on either below or above the lasing threshold. Furthermore, our random laser functions as a stable and durable optical strain gauge with a gauge factor of ≈37.7  5.4 under a bending strain of 40%, which is comparable to that of traditional electrical strain gauges. The study validates that the reported strain-gauge random laser is able to be used in certain fields where the electrical gauge is restricted and the optical gauge is considered to preferable as an alternative solution. The research results of this paper have been submitted to APL Materials (10.1063 / 1.5099316).

    3. Graphene Quantum Dot Vertical Cavity Surface Emitting Lasers
    Nonzero-bandgap graphene quantum dots (GQDs) are novel optical gain materials promising for solution-processed light sources with high cost efficiency and device performance. Herein, we demonstrate for the first time room-temperature lasing emission with green gamut from GQDs in a vertical optical cavity composed of Ta2O5/SiO2 dielectric distributed Bragg reflectors (DBRs). The lasing is enabled by the unique design of the DBR which not only provides a wide stopband spectrally overlapping with the emission of the GQDs but also allows high transmittance of optical excitation in the UV-light region. This demonstration is a clear evidence of the use of GQDs as optical gain materials and represents an important step forward toward their potential applications in wide-gamut laser displays and projectors. The research results of this paper have been submitted to ACS photonics (10.1021 / acsphotonics.9b00976).

    誌謝 I 摘要 III Abstract VI Contents X List of Figures XIII List of Table XVI Chapter 1 Introduction 1 1.1 Laser Technology Demand and Development 1 1.2 Research Motivation and Laser Applications 2 1.3 Literature Review 5 1.3.1 Flexible Random Lasers with Tunable Lasing Emissions 5 1.3.2 Random Laser Action in GaN Nanocolumns 8 1.3.3 Highly Stretchable and Wearable Strain Sensor Based on Printable Carbon Nanotube Layers/Polydimethylsiloxane Composites with Adjustable Sensitivity 8 1.3.4 CsPbBr3 Perovskite Quantum Dot Vertical Cavity Lasers with Low Threshold and High Stability 10 1.3.5 Solution‐processed Low Threshold Vertical Cavity Surface Emitting Lasers from All‐inorganic Perovskite Nanocrystals 11 Chapter 2 Laser Theory 13 2.1 Principle of Laser 13 2.1.1 Light and Matter Interaction 13 2.1.2 Population Inversion and Light Amplification 16 2.2 Fundamentals of Laser 19 2.2.1 Traditional Laser 19 2.2.2 Random Laser 20 2.2.3 Vertical Cavity Surface Emitting Lasers (VCSEL) 21 2.3 Laser Characteristics 23 2.3.1 Properties of Laser Radiation 23 2.3.2 Laser Radiation Parameters 24 2.3.3 Summary of the Laser Beam Parameters 26 Chapter 3 A Curvature-tunable Random Laser 28 3.1 Introduction 28 3.2 Methods 30 3.2.1 Synthesis of ZnO Nanowires 30 3.2.2 Device Fabrication 31 3.2.3 Characterization 31 3.3 Results and Discussion 32 3.4 Conclusions 52 Chapter 4 A Strain-gauge Random Laser 53 4.1 Introduction 53 4.2 Results and Discussion 55 4.3 Conclusions 70 Chapter 5 Graphene Quantum Dot Vertical Cavity Surface Emitting Lasers 71 5.1 Introduction 71 5.2 Methods 74 5.2.1 Graphene Quantum Dot Synthesis 74 5.2.2 DBR Fabrication 74 5.2.3 Optical Measurements 74 5.2.4 Material Characterization 75 5.2.5 The Matrix Optics Methods 75 5.3 Results and Discussion 77 5.4 Conclusions 92 Chapter 6 Conclusions and Future Work 93 References 95 Appendix : Publications, Awards & Honors 112 Publications 112 Journal Paper 112 Conference Paper 113 Awards & Honors 116

    [1] O. G. Okhotnikov, Fiber lasers. John Wiley & Sons, 2012.
    [2] A. Shirakawa, T. Saitou, T. Sekiguchi, and K.-i. Ueda, "Coherent addition of fiber lasers by use of a fiber coupler," Optics Express, vol. 10, no. 21, pp. 1167-1172, 2002.
    [3] D. J. Richardson, J. Nilsson, and W. Clarkson, "High power fiber lasers: current status and future perspectives," JOSA B, vol. 27, no. 11, pp. B63-B92, 2010.
    [4] L. Reekie, R. Mears, S. Poole, and D. Payne, "Tunable single-mode fiber lasers," Journal of lightwave technology, vol. 4, no. 7, pp. 956-960, 1986.
    [5] J. Limpert et al., "The rising power of fiber lasers and amplifiers," IEEE Journal of Selected Topics in Quantum Electronics, vol. 13, no. 3, pp. 537-545, 2007.
    [6] R. Stolen, "Polarization effects in fiber Raman and Brillouin lasers," IEEE Journal of Quantum Electronics, vol. 15, no. 10, pp. 1157-1160, 1979.
    [7] W. Shi, Q. Fang, X. Zhu, R. A. Norwood, and N. Peyghambarian, "Fiber lasers and their applications," Applied Optics, vol. 53, no. 28, pp. 6554-6568, 2014.
    [8] E. Snitzer, H. Po, R. P. Tumminelli, and F. Hakimi, "Optical fiber lasers and amplifiers," ed: Google Patents, 1989.
    [9] D. G. Cahill and S. M. Yalisove, "Ultrafast lasers in materials research," MRS Bulletin, vol. 31, no. 8, pp. 594-600, 2006.
    [10] J. R. Gord, T. R. Meyer, and S. Roy, "Applications of ultrafast lasers for optical measurements in combusting flows," 2008.
    [11] P. Gallagher et al., "Quantum-critical conductivity of the Dirac fluid in graphene," Science, vol. 364, no. 6436, pp. 158-162, 2019.
    [12] K. Sugioka and Y. Cheng, "Ultrafast lasers—reliable tools for advanced materials processing," Light: Science & Applications, vol. 3, no. 4, p. e149, 2014.
    [13] A. Sugar, "Ultrafast (femtosecond) laser refractive surgery," Current opinion in ophthalmology, vol. 13, no. 4, pp. 246-249, 2002.
    [14] S. Amini-Nik et al., "Ultrafast mid-IR laser scalpel: protein signals of the fundamental limits to minimally invasive surgery," PloS one, vol. 5, no. 9, p. e13053, 2010.
    [15] T. Juhasz, F. H. Loesel, R. M. Kurtz, C. Horvath, J. F. Bille, and G. Mourou, "Corneal refractive surgery with femtosecond lasers," IEEE Journal of Selected Topics in Quantum Electronics, vol. 5, no. 4, pp. 902-910, 1999.
    [16] P. L. Gourley et al., "Mitochondrial correlation microscopy and nanolaser spectroscopy—new tools for biophotonic detection of cancer in single cells," Technology in cancer research & treatment, vol. 4, no. 6, pp. 585-592, 2005.
    [17] N. Roy, A. Yuksel, and M. Cullinan, "Design and modeling of a microscale selective laser sintering system," in ASME 2016 11th International Manufacturing Science and Engineering Conference, 2016: American Society of Mechanical Engineers Digital Collection.
    [18] M. Jarczynski, T. Mitra, and S. Brüning, "Ultrashort pulsed multibeam processing head for parallel ultrafast micromachining," Journal of Laser Applications, vol. 29, no. 2, p. 022214, 2017.
    [19] X. Liu and G. Mourou, "Ultrashort laser pulses tackle precision machining," Laser Focus World, vol. 33, no. 8, pp. 101-122, 1997.
    [20] M. D. Perry and B. C. Stuart, "Ultrashort pulse laser machining of metals and alloys," ed: Google Patents, 2003.
    [21] E. U. Rafailov, M. A. Cataluna, and E. A. Avrutin, Ultrafast lasers based on quantum dot structures: physics and devices. John Wiley & Sons, 2011.
    [22] E. D. Hinkley, "Laser monitoring of the atmosphere," in Berlin and New York, Springer-Verlag (Topics in Applied Physics. Volume 14), 1976. 396 p, 1976, vol. 14.
    [23] G. Ball, W. Morey, and P. Cheo, "Single-and multipoint fiber-laser sensors," IEEE Photonics Technology Letters, vol. 5, no. 2, pp. 267-270, 1993.
    [24] B. Redding, M. A. Choma, and H. Cao, "Speckle-free laser imaging using random laser illumination," Nature photonics, vol. 6, no. 6, p. 355, 2012.
    [25] A. E. Dixon and S. Damaskinos, "Scanning laser imaging system," ed: Google Patents, 1995.
    [26] M. Yamamoto, "Laser imaging device," ed: Google Patents, 1974.
    [27] H. Ogiu, "Endoscope provided with an elongate medical treating instrument utilizing laser beams," ed: Google Patents, 1983.
    [28] D. S. Choy, "Laser tunnelling device," ed: Google Patents, 1980.
    [29] M.-T. Tsai et al., "early detection of enamel demineralization by optical coherence tomography," Scientific reports, vol. 9, no. 1, pp. 1-9, 2019.
    [30] S. P. DenBaars et al., "Development of gallium-nitride-based light-emitting diodes (LEDs) and laser diodes for energy-efficient lighting and displays," Acta Materialia, vol. 61, no. 3, pp. 945-951, 2013.
    [31] B. E. Kruschwitz and A. F. Kurtz, "Laser projection display system," ed: Google Patents, 2003.
    [32] J. W. Raring and P. Rudy, "Laser based display method and system," ed: Google Patents, 2013.
    [33] A. F. Kurtz, B. E. Kruschwitz, and S. Ramanujan, "Laser projection display system," ed: Google Patents, 2003.
    [34] D. S. Wiersma and S. Cavalieri, "Light emission: A temperature-tunable random laser," Nature, vol. 414, no. 6865, p. 708, 2001.
    [35] S. Gottardo, R. Sapienza, P. D. García, A. Blanco, D. S. Wiersma, and C. López, "Resonance-driven random lasing," Nature Photonics, vol. 2, no. 7, p. 429, 2008.
    [36] T.-M. Sun et al., "Stretchable random lasers with tunable coherent loops," ACS nano, vol. 9, no. 12, pp. 12436-12441, 2015.
    [37] T. Zhai et al., "A plasmonic random laser tunable through stretching silver nanowires embedded in a flexible substrate," Nanoscale, vol. 7, no. 6, pp. 2235-2240, 2015.
    [38] P. Görrn, M. Lehnhardt, W. Kowalsky, T. Riedl, and S. Wagner, "Elastically Tunable Self‐Organized Organic Lasers," Advanced Materials, vol. 23, no. 7, pp. 869-872, 2011.
    [39] Z. Wang et al., "Controlling random lasing with three-dimensional plasmonic nanorod metamaterials," Nano letters, vol. 16, no. 4, pp. 2471-2477, 2016.
    [40] H. Mertens, J. S. Biteen, H. A. Atwater, and A. Polman, "Polarization-selective plasmon-enhanced silicon quantum-dot luminescence," Nano letters, vol. 6, no. 11, pp. 2622-2625, 2006.
    [41] Y.-J. Lee et al., "Flexible random lasers with tunable lasing emissions," Nanoscale, vol. 10, no. 22, pp. 10403-10411, 2018.
    [42] T. Yamada et al., "A stretchable carbon nanotube strain sensor for human-motion detection," Nature nanotechnology, vol. 6, no. 5, p. 296, 2011.
    [43] J. Zhou et al., "Flexible piezotronic strain sensor," Nano letters, vol. 8, no. 9, pp. 3035-3040, 2008.
    [44] S.-H. Bae, Y. Lee, B. K. Sharma, H.-J. Lee, J.-H. Kim, and J.-H. Ahn, "Graphene-based transparent strain sensor," Carbon, vol. 51, pp. 236-242, 2013.
    [45] A. D. Kersey, T. Berkoff, and W. Morey, "Multiplexed fiber Bragg grating strain-sensor system with a fiber Fabry–Perot wavelength filter," Optics letters, vol. 18, no. 16, pp. 1370-1372, 1993.
    [46] I. Kang, M. J. Schulz, J. H. Kim, V. Shanov, and D. Shi, "A carbon nanotube strain sensor for structural health monitoring," Smart materials and structures, vol. 15, no. 3, p. 737, 2006.
    [47] A. Kersey, T. Berkoff, and W. Morey, "High-resolution fibre-grating based strain sensor with interferometric wavelength-shift detection," Electronics Letters, vol. 28, no. 3, pp. 236-238, 1992.
    [48] N. Hu, Y. Karube, C. Yan, Z. Masuda, and H. Fukunaga, "Tunneling effect in a polymer/carbon nanotube nanocomposite strain sensor," Acta Materialia, vol. 56, no. 13, pp. 2929-2936, 2008.
    [49] C. Mattmann, F. Clemens, and G. Tröster, "Sensor for measuring strain in textile," Sensors, vol. 8, no. 6, pp. 3719-3732, 2008.
    [50] C. Pang et al., "A flexible and highly sensitive strain-gauge sensor using reversible interlocking of nanofibres," Nature materials, vol. 11, no. 9, p. 795, 2012.
    [51] C. Belleville and G. Duplain, "White-light interferometric multimode fiber-optic strain sensor," Optics letters, vol. 18, no. 1, pp. 78-80, 1993.
    [52] K. D. Choquette and J. K. Guenter, "Vertical-Cavity Surface-Emitting Lasers XX," in Proc. of SPIE Vol, 2016, vol. 9766, pp. 976601-1.
    [53] R. Rodes et al., "High-speed 1550 nm VCSEL data transmission link employing 25 GBd 4-PAM modulation and hard decision forward error correction," Journal of Lightwave Technology, vol. 31, no. 4, pp. 689-695, 2012.
    [54] F. Koyama, "Recent advances of VCSEL photonics," Journal of Lightwave Technology, vol. 24, no. 12, pp. 4502-4513, 2006.
    [55] T.-C. Lu et al., "Continuous wave operation of current injected GaN vertical cavity surface emitting lasers at room temperature," Applied Physics Letters, vol. 97, no. 7, p. 071114, 2010.
    [56] Y. Mei et al., "Quantum dot vertical-cavity surface-emitting lasers covering the ‘green gap’," Light: Science & Applications, vol. 6, no. 1, p. e16199, 2017.
    [57] M. Sakai et al., "Random laser action in GaN nanocolumns," Applied Physics Letters, vol. 97, no. 15, p. 151109, 2010.
    [58] X. Wang, J. Li, H. Song, H. Huang, and J. Gou, "Highly stretchable and wearable strain sensor based on printable carbon nanotube layers/polydimethylsiloxane composites with adjustable sensitivity," ACS applied materials & interfaces, vol. 10, no. 8, pp. 7371-7380, 2018.
    [59] C.-Y. Huang et al., "CsPbBr3 perovskite quantum dot vertical cavity lasers with low threshold and high stability," Acs Photonics, vol. 4, no. 9, pp. 2281-2289, 2017.
    [60] Y. Wang, X. Li, V. Nalla, H. Zeng, and H. Sun, "Solution‐processed low threshold vertical cavity surface emitting lasers from all‐inorganic perovskite nanocrystals," Advanced Functional Materials, vol. 27, no. 13, p. 1605088, 2017.
    [61] H. Jelinkova and J. Šulc, "Laser characteristics," in Lasers for Medical Applications: Elsevier, 2013, pp. 17-46.
    [62] D. Wiersma, "Laser physics: The smallest random laser," Nature, vol. 406, no. 6792, p. 132, 2000.
    [63] B. J. Bijlani and A. S. Helmy, "Design methodology for efficient frequency conversion in Bragg reflection lasers," JOSA B, vol. 29, no. 9, pp. 2484-2492, 2012.
    [64] A. Liu, P. Wolf, J. A. Lott, and D. Bimberg, "Vertical-cavity surface-emitting lasers for data communication and sensing," Photonics Research, vol. 7, no. 2, pp. 121-136, 2019.
    [65] D. S. Wiersma, "The physics and applications of random lasers," Nature physics, vol. 4, no. 5, p. 359, 2008.
    [66] H. Cao, "Random lasers: development, features and applications," Optics and photonics news, vol. 16, no. 1, pp. 24-29, 2005.
    [67] J. Fallert, R. J. Dietz, J. Sartor, D. Schneider, C. Klingshirn, and H. Kalt, "Co-existence of strongly and weakly localized random laser modes," Nature Photonics, vol. 3, no. 5, p. 279, 2009.
    [68] B. Redding, M. A. Choma, and H. Cao, "Speckle-free laser imaging using random laser illumination," Nature photonics, vol. 6, no. 6, p. 355, 2012.
    [69] B. H. Rotstein, N. A. Stephenson, N. Vasdev, and S. H. Liang, "Spirocyclic hypervalent iodine (III)-mediated radiofluorination of non-activated and hindered aromatics," Nature communications, vol. 5, p. 4365, 2014.
    [70] X. Shi et al., "Dissolvable and recyclable random lasers," ACS nano, vol. 11, no. 8, pp. 7600-7607, 2017.
    [71] Y. C. Yao et al., "Coherent and polarized random laser emissions from colloidal CdSe/ZnS quantum dots plasmonically coupled to ellipsoidal Ag nanoparticles," Advanced Optical Materials, vol. 5, no. 3, p. 1600746, 2017.
    [72] M. Anderson and J. Ensher, "MR 1\/Ie. tt11ews, GE Wiernan e EA Cornell," Science, vol. 269, p. 198, 1995.
    [73] H. Deng, G. Weihs, C. Santori, J. Bloch, and Y. Yamamoto, "Condensation of semiconductor microcavity exciton polaritons," Science, vol. 298, no. 5591, pp. 199-202, 2002.
    [74] Y.-Y. Lai, Y.-P. Lan, and T.-C. Lu, "Strong light–matter interaction in ZnO microcavities," Light: Science & Applications, vol. 2, no. 6, p. e76, 2013.
    [75] P. W. Anderson, "Absence of diffusion in certain random lattices," Physical review, vol. 109, no. 5, p. 1492, 1958.
    [76] D. S. Wiersma, P. Bartolini, A. Lagendijk, and R. Righini, "Localization of light in a disordered medium," Nature, vol. 390, no. 6661, p. 671, 1997.
    [77] P. Stano and P. Jacquod, "Suppression of interactions in multimode random lasers in the Anderson localized regime," Nature Photonics, vol. 7, no. 1, p. 66, 2013.
    [78] M. Segev, Y. Silberberg, and D. N. Christodoulides, "Anderson localization of light," Nature Photonics, vol. 7, no. 3, p. 197, 2013.
    [79] J. Liu et al., "Random nanolasing in the Anderson localized regime," Nature Nanotechnology, vol. 9, no. 4, p. 285, 2014.
    [80] T. Crane, O. J. Trojak, J. P. Vasco, S. Hughes, and L. Sapienza, "Anderson localization of visible light on a nanophotonic chip," ACS Photonics, vol. 4, no. 9, pp. 2274-2280, 2017.
    [81] R. Polson and Z. Vardeny, "Organic random lasers in the weak-scattering regime," Physical Review B, vol. 71, no. 4, p. 045205, 2005.
    [82] G. Dice, S. Mujumdar, and A. Elezzabi, "Plasmonically enhanced diffusive and subdiffusive metal nanoparticle-dye random laser," Applied Physics Letters, vol. 86, no. 13, p. 131105, 2005.
    [83] Z. Hu et al., "Coherent random fiber laser based on nanoparticles scattering in the extremely weakly scattering regime," Physical review letters, vol. 109, no. 25, p. 253901, 2012.
    [84] Y.-J. Lee et al., "Flexible random lasers with tunable lasing emissions," Nanoscale, vol. 10, no. 22, pp. 10403-10411, 2018.
    [85] E. Ignesti, F. Tommasi, L. Fini, F. Martelli, N. Azzali, and S. Cavalieri, "A new class of optical sensors: a random laser based device," Scientific reports, vol. 6, p. 35225, 2016.
    [86] Y. Xu, L. Zhang, S. Gao, P. Lu, S. Mihailov, and X. Bao, "Highly sensitive fiber random-grating-based random laser sensor for ultrasound detection," Optics letters, vol. 42, no. 7, pp. 1353-1356, 2017.
    [87] M. Barredo-Zuriarrain, I. Iparraguirre, J. Fernández, J. Azkargorta, and R. Balda, "Speckle-free near-infrared imaging using a Nd3+ random laser," Laser Physics Letters, vol. 14, no. 10, p. 106201, 2017.
    [88] R. C. Polson and Z. V. Vardeny, "Random lasing in human tissues," Applied physics letters, vol. 85, no. 7, pp. 1289-1291, 2004.
    [89] Y. Wang et al., "Random lasing in human tissues embedded with organic dyes for cancer diagnosis," Scientific reports, vol. 7, no. 1, p. 8385, 2017.
    [90] F. Lahoz et al., "Random laser in biological tissues impregnated with a fluorescent anticancer drug," Laser Physics Letters, vol. 12, no. 4, p. 045805, 2015.
    [91] D. S. Wiersma and S. Cavalieri, "Light emission: A temperature-tunable random laser," Nature, vol. 414, no. 6865, p. 708, 2001.
    [92] S. Gottardo, R. Sapienza, P. D. García, A. Blanco, D. S. Wiersma, and C. López, "Resonance-driven random lasing," Nature Photonics, vol. 2, no. 7, p. 429, 2008.
    [93] T.-M. Sun et al., "Stretchable random lasers with tunable coherent loops," ACS nano, vol. 9, no. 12, pp. 12436-12441, 2015.
    [94] T. Zhai et al., "A plasmonic random laser tunable through stretching silver nanowires embedded in a flexible substrate," Nanoscale, vol. 7, no. 6, pp. 2235-2240, 2015.
    [95] P. Görrn, M. Lehnhardt, W. Kowalsky, T. Riedl, and S. Wagner, "Elastically Tunable Self‐Organized Organic Lasers," Advanced Materials, vol. 23, no. 7, pp. 869-872, 2011.
    [96] Z. Wang et al., "Controlling random lasing with three-dimensional plasmonic nanorod metamaterials," Nano letters, vol. 16, no. 4, pp. 2471-2477, 2016.
    [97] H. Mertens, J. S. Biteen, H. A. Atwater, and A. Polman, "Polarization-selective plasmon-enhanced silicon quantum-dot luminescence," Nano letters, vol. 6, no. 11, pp. 2622-2625, 2006.
    [98] Y. M. Liao et al., "Highly stretchable label‐like random laser on universal substrates," Advanced Materials Technologies, vol. 1, no. 6, p. 1600068, 2016.
    [99] X. Shi et al., "Random lasing with a high quality factor over the whole visible range based on cascade energy transfer," Advanced Optical Materials, vol. 2, no. 1, pp. 88-93, 2014.
    [100] Z. Wang et al., "Single-excitation dual-color coherent lasing by tuning resonance energy transfer processes in porous structured nanowires," Nanoscale, vol. 7, no. 37, pp. 15091-15098, 2015.
    [101] O. Lupan et al., "Synthesis and characterization of ZnO nanowires for nanosensor applications," Materials Research Bulletin, vol. 45, no. 8, pp. 1026-1032, 2010.
    [102] N. Garcia, A. Genack, and A. Lisyansky, "Measurement of the transport mean free path of diffusing photons," Physical Review B, vol. 46, no. 22, p. 14475, 1992.
    [103] R. Sapienza et al., "Observation of resonant behavior in the energy velocity of diffused light," Physical review letters, vol. 99, no. 23, p. 233902, 2007.
    [104] T. Zhai et al., "Random laser based on waveguided plasmonic gain channels," Nano letters, vol. 11, no. 10, pp. 4295-4298, 2011.
    [105] J. Frank, D. Vanmaekelbergh, J. van de Lagemaat, and A. Lagendijk, "Strongly photonic macroporous gallium phosphide networks," Science, vol. 284, no. 5411, pp. 141-143, 1999.
    [106] X. Meng, K. Fujita, S. Murai, and K. Tanaka, "Coherent random lasers in weakly scattering polymer films containing silver nanoparticles," Physical Review A, vol. 79, no. 5, p. 053817, 2009.
    [107] M. Draijer, E. Hondebrink, T. van Leeuwen, and W. Steenbergen, "Review of laser speckle contrast techniques for visualizing tissue perfusion," Lasers in medical science, vol. 24, no. 4, p. 639, 2009.
    [108] D. A. Boas and A. K. Dunn, "Laser speckle contrast imaging in biomedical optics," Journal of biomedical optics, vol. 15, no. 1, p. 011109, 2010.
    [109] A. Nathan et al., "Flexible electronics: the next ubiquitous platform," Proceedings of the IEEE, vol. 100, no. Special Centennial Issue, pp. 1486-1517, 2012.
    [110] D. Akinwande, N. Petrone, and J. Hone, "Two-dimensional flexible nanoelectronics," Nature communications, vol. 5, p. 5678, 2014.
    [111] G. Fiori et al., "Electronics based on two-dimensional materials," Nature nanotechnology, vol. 9, no. 10, p. 768, 2014.
    [112] H. Gullapalli et al., "Flexible piezoelectric ZnO–paper nanocomposite strain sensor," small, vol. 6, no. 15, pp. 1641-1646, 2010.
    [113] D. J. Lipomi et al., "Skin-like pressure and strain sensors based on transparent elastic films of carbon nanotubes," Nature nanotechnology, vol. 6, no. 12, p. 788, 2011.
    [114] H. Høyer, M. Knaapila, J. Kjelstrup-Hansen, X. Liu, and G. Helgesen, "A strain sensor based on an aligned carbon particle string in a UV-cured polymer matrix," Applied Physics Letters, vol. 99, no. 21, p. 213106, 2011.
    [115] T.-H. Kim et al., "Fully stretchable optoelectronic sensors based on colloidal quantum dots for sensing photoplethysmographic signals," ACS nano, vol. 11, no. 6, pp. 5992-6003, 2017.
    [116] Y. Lee et al., "Wafer-scale synthesis and transfer of graphene films," Nano letters, vol. 10, no. 2, pp. 490-493, 2010.
    [117] S.-H. Bae, Y. Lee, B. K. Sharma, H.-J. Lee, J.-H. Kim, and J.-H. Ahn, "Graphene-based transparent strain sensor," Carbon, vol. 51, pp. 236-242, 2013.
    [118] N.-K. Chang, C.-C. Su, and S.-H. Chang, "Fabrication of single-walled carbon nanotube flexible strain sensors with high sensitivity," Applied Physics Letters, vol. 92, no. 6, p. 063501, 2008.
    [119] X. Xiao et al., "High‐strain sensors based on ZnO nanowire/polystyrene hybridized flexible films," Advanced materials, vol. 23, no. 45, pp. 5440-5444, 2011.
    [120] S. Shengbo et al., "Highly sensitive wearable strain sensor based on silver nanowires and nanoparticles," Nanotechnology, vol. 29, no. 25, p. 255202, 2018.
    [121] H. Y. Choi, K. S. Park, and B. H. Lee, "Photonic crystal fiber interferometer composed of a long period fiber grating and one point collapsing of air holes," Optics Letters, vol. 33, no. 8, pp. 812-814, 2008.
    [122] M.-S. Yoon, S. Park, and Y.-G. Han, "Simultaneous measurement of strain and temperature by using a micro-tapered fiber grating," Journal of Lightwave Technology, vol. 30, no. 8, pp. 1156-1160, 2011.
    [123] X. Bai, D. Fan, S. Wang, S. Pu, and X. Zeng, "Strain sensor based on fiber ring cavity laser with photonic crystal fiber in-line Mach–Zehnder interferometer," IEEE Photonics Journal, vol. 6, no. 4, pp. 1-8, 2014.
    [124] J.-H. Choi et al., "A high-resolution strain-gauge nanolaser," Nature communications, vol. 7, p. 11569, 2016.
    [125] T.-W. Lu, C.-C. Wu, and P.-T. Lee, "1D photonic crystal strain sensors," ACS Photonics, vol. 5, no. 7, pp. 2767-2772, 2018.
    [126] H. Cao, Y. Zhao, S.-T. Ho, E. Seelig, Q. Wang, and R. P. Chang, "Random laser action in semiconductor powder," Physical Review Letters, vol. 82, no. 11, p. 2278, 1999.
    [127] Y. Wu et al., "A one-dimensional random laser based on artificial high-index contrast scatterers," Nanoscale, vol. 9, no. 21, pp. 6959-6964, 2017.
    [128] Y. Ren et al., "Ultraviolet Random Laser Based on a Single GaN Microwire," ACS Photonics, vol. 5, no. 6, pp. 2503-2508, 2018.
    [129] Y. C. Yao et al., "Coherent and polarized random laser emissions from colloidal CdSe/ZnS quantum dots plasmonically coupled to ellipsoidal Ag nanoparticles," Advanced Optical Materials, vol. 5, no. 3, p. 1600746, 2017.
    [130] Y.-C. Yao et al., "Enhancing UV-emissions through optical and electronic dual-function tuning of Ag nanoparticles hybridized with n-ZnO nanorods/p-GaN heterojunction light-emitting diodes," Nanoscale, vol. 8, no. 8, pp. 4463-4474, 2016.
    [131] T. Horio and H. Hotani, "Visualization of the dynamic instability of individual microtubules by dark-field microscopy," Nature, vol. 321, no. 6070, p. 605, 1986.
    [132] V. Letokhov, "Quantum statistics of multiple-mode emission of an atomic ensemble," Sov. Phys. JETP, vol. 26, pp. 1246-1251, 1968.
    [133] H. Cao, "Lasing in random media," Waves in random media, vol. 13, no. 3, pp. R1-R39, 2003.
    [134] C. Mattmann, F. Clemens, and G. Tröster, "Sensor for measuring strain in textile," Sensors, vol. 8, no. 6, pp. 3719-3732, 2008.
    [135] Y. Kanda, "Piezoresistance effect of silicon," Sensors and Actuators A: Physical, vol. 28, no. 2, pp. 83-91, 1991.
    [136] P. Cheney et al., "Label-free hyperspectral dark-field microscopy for quantitative scatter imaging," in Design and Quality for Biomedical Technologies X, 2017, vol. 10056: International Society for Optics and Photonics, p. 1005602.
    [137] K. Busch, C. Soukoulis, and E. Economou, "Transport and scattering mean free paths of classical waves," Physical Review B, vol. 50, no. 1, p. 93, 1994.
    [138] R. Sapienza et al., "Observation of resonant behavior in the energy velocity of diffused light," Physical review letters, vol. 99, no. 23, p. 233902, 2007.
    [139] J. F. de Boer, M. Van Rossum, M. P. van Albada, T. M. Nieuwenhuizen, and A. Lagendijk, "Probability distribution of multiple scattered light measured in total transmission," Physical review letters, vol. 73, no. 19, p. 2567, 1994.
    [140] S.-H. Choi, "Unique properties of graphene quantum dots and their applications in photonic/electronic devices," Journal of Physics D: Applied Physics, vol. 50, no. 10, p. 103002, 2017.
    [141] J. Shen, Y. Zhu, C. Chen, X. Yang, and C. Li, "Facile preparation and upconversion luminescence of graphene quantum dots," Chemical communications, vol. 47, no. 9, pp. 2580-2582, 2011.
    [142] X. Yan, X. Cui, and L.-s. Li, "Synthesis of large, stable colloidal graphene quantum dots with tunable size," Journal of the American Chemical Society, vol. 132, no. 17, pp. 5944-5945, 2010.
    [143] L. Ponomarenko et al., "Chaotic Dirac billiard in graphene quantum dots," Science, vol. 320, no. 5874, pp. 356-358, 2008.
    [144] K. A. Ritter and J. W. Lyding, "The influence of edge structure on the electronic properties of graphene quantum dots and nanoribbons," Nature materials, vol. 8, no. 3, p. 235, 2009.
    [145] D. Pan, J. Zhang, Z. Li, and M. Wu, "Hydrothermal route for cutting graphene sheets into blue‐luminescent graphene quantum dots," Advanced materials, vol. 22, no. 6, pp. 734-738, 2010.
    [146] W. Zhang, H. Zhu, S. Yu, and H. Yang, "Observation of lasing emission from carbon nanodots in organic solvents," Advanced Materials, vol. 24, no. 17, pp. 2263-2267, 2012.
    [147] T. Gao et al., "Red, yellow, and blue luminescence by graphene quantum dots: syntheses, mechanism, and cellular imaging," ACS applied materials & interfaces, vol. 9, no. 29, pp. 24846-24856, 2017.
    [148] G. Haider et al., "Dirac point induced ultralow-threshold laser and giant optoelectronic quantum oscillations in graphene-based heterojunctions," Nature communications, vol. 8, no. 1, p. 256, 2017.
    [149] L. L. Li et al., "A facile microwave avenue to electrochemiluminescent two‐color graphene quantum dots," Advanced Functional Materials, vol. 22, no. 14, pp. 2971-2979, 2012.
    [150] C. Luk, L. Tang, W. Zhang, S. Yu, K. Teng, and S. Lau, "An efficient and stable fluorescent graphene quantum dot–agar composite as a converting material in white light emitting diodes," Journal of Materials Chemistry, vol. 22, no. 42, pp. 22378-22381, 2012.
    [151] M. Cao et al., "Tunable amplified spontaneous emission in graphene quantum dots doped cholesteric liquid crystals," Nanotechnology, vol. 28, no. 24, p. 245202, 2017.
    [152] T.-N. Lin et al., "Enhanced performance of GaN-based ultraviolet light emitting diodes by photon recycling using graphene quantum dots," Scientific reports, vol. 7, no. 1, p. 7108, 2017.
    [153] Z. Tian et al., "Ultraviolet-pumped white light emissive carbon dot based phosphors for light-emitting devices and visible light communication," Nanoscale, vol. 11, no. 8, pp. 3489-3494, 2019.
    [154] C. Dang, J. Lee, C. Breen, J. S. Steckel, S. Coe-Sullivan, and A. Nurmikko, "Red, green and blue lasing enabled by single-exciton gain in colloidal quantum dot films," Nature nanotechnology, vol. 7, no. 5, p. 335, 2012.
    [155] Y. C. Yao et al., "Coherent and polarized random laser emissions from colloidal CdSe/ZnS quantum dots plasmonically coupled to ellipsoidal Ag nanoparticles," Advanced Optical Materials, vol. 5, no. 3, p. 1600746, 2017.
    [156] Y. Li et al., "Room-temperature continuous-wave lasing from monolayer molybdenum ditelluride integrated with a silicon nanobeam cavity," Nature nanotechnology, vol. 12, no. 10, p. 987, 2017.
    [157] D. G. Lidzey, D. Bradley, M. Skolnick, T. Virgili, S. Walker, and D. Whittaker, "Strong exciton–photon coupling in an organic semiconductor microcavity," Nature, vol. 395, no. 6697, p. 53, 1998.
    [158] H. Zhu, W. Zhang, and S. F. Yu, "Realization of lasing emission from graphene quantum dots using titanium dioxide nanoparticles as light scatterers," Nanoscale, vol. 5, no. 5, pp. 1797-1802, 2013.
    [159] S. Gottardo, R. Sapienza, P. D. García, A. Blanco, D. S. Wiersma, and C. López, "Resonance-driven random lasing," Nature Photonics, vol. 2, no. 7, p. 429, 2008.
    [160] Y.-J. Lee et al., "Flexible random lasers with tunable lasing emissions," Nanoscale, vol. 10, no. 22, pp. 10403-10411, 2018.
    [161] H. Moench et al., "VCSEL-based sensors for distance and velocity," in Vertical-Cavity Surface-Emitting Lasers XX, 2016, vol. 9766: International Society for Optics and Photonics, p. 97660A.
    [162] R. Rodes et al., "High-speed 1550 nm VCSEL data transmission link employing 25 GBd 4-PAM modulation and hard decision forward error correction," Journal of Lightwave Technology, vol. 31, no. 4, pp. 689-695, 2012.
    [163] F. Koyama, "Recent advances of VCSEL photonics," Journal of Lightwave Technology, vol. 24, no. 12, pp. 4502-4513, 2006.
    [164] Y. Mei et al., "Quantum dot vertical-cavity surface-emitting lasers covering the ‘green gap’," Light: Science & Applications, vol. 6, no. 1, p. e16199, 2017.
    [165] T.-C. Lu et al., "Continuous wave operation of current injected GaN vertical cavity surface emitting lasers at room temperature," Applied Physics Letters, vol. 97, no. 7, p. 071114, 2010.
    [166] K. Iga, "Surface-emitting laser-its birth and generation of new optoelectronics field," IEEE Journal of Selected Topics in Quantum Electronics, vol. 6, no. 6, pp. 1201-1215, 2000.
    [167] K. D. Choquette, D. Richie, and R. Leibenguth, "Temperature dependence of gain‐guided vertical‐cavity surface emitting laser polarization," Applied physics letters, vol. 64, no. 16, pp. 2062-2064, 1994.
    [168] S. Fujita, "Wide-bandgap semiconductor materials: For their full bloom," Japanese journal of applied physics, vol. 54, no. 3, p. 030101, 2015.
    [169] M. A. Der Maur, A. Pecchia, G. Penazzi, W. Rodrigues, and A. Di Carlo, "Efficiency drop in green InGaN/GaN light emitting diodes: The role of random alloy fluctuations," Physical review letters, vol. 116, no. 2, p. 027401, 2016.
    [170] M. R. Krames et al., "Status and future of high-power light-emitting diodes for solid-state lighting," Journal of display technology, vol. 3, no. 2, pp. 160-175, 2007.
    [171] L. Tang et al., "Deep ultraviolet photoluminescence of water-soluble self-passivated graphene quantum dots," ACS nano, vol. 6, no. 6, pp. 5102-5110, 2012.
    [172] Z. Luo, Y. Lu, L. A. Somers, and A. C. Johnson, "High yield preparation of macroscopic graphene oxide membranes," Journal of the American Chemical Society, vol. 131, no. 3, pp. 898-899, 2009.
    [173] H. He et al., "Exciton localization in solution-processed organolead trihalide perovskites," Nature communications, vol. 7, p. 10896, 2016.
    [174] X. Deng et al., "The emission wavelength dependent photoluminescence lifetime of the N-doped graphene quantum dots," Applied Physics Letters, vol. 107, no. 24, p. 241905, 2015.
    [175] M. Röding, S. J. Bradley, M. Nydén, and T. Nann, "Fluorescence lifetime analysis of graphene quantum dots," The Journal of Physical Chemistry C, vol. 118, no. 51, pp. 30282-30290, 2014.
    [176] G. R. Fowles, Introduction to Modern Optics. Courier Corporation, 2012.

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