Now showing items 1-20 of 266

    • Wide-field-of-view optical detectors using fused fiber-optic tapers

      Alkhazragi, Omar; Trichili, Abderrahmen; Ashry, Islam; Ng, Tien Khee; Alouini, Mohamed-Slim; Ooi, Boon S. (Optics Letters, The Optical Society, 2021-04-12) [Article]
      Photodetectors used in wireless applications suffer from a trade-off between their response speeds and their active areas, which limits the received signal-to-noise ratio (SNR). Conventional light-focusing elements used to improve the SNR narrow the field of view (FOV). Herein, we demonstrate a versatile imaging light-focusing element featuring a wide FOV and high optical gain using fused fiber-optic tapers. To verify the practicality of the proposed design, we demonstrated and tested a wide-FOV optical detector for optical wireless communication that can be used for wavelengths ranging from the visible-light band to the near infrared. The proposed detector offers improvements over luminescent wide-FOV detectors, including higher efficiency, a broader modulation bandwidth, and indefinite stability.
    • Vapor condensation with daytime radiative cooling

      Zhou, Ming; Song, Haomin; Xu, Xingyu; Shahsafi, Alireza; Qu, Yurui; Xia, Zhenyang; Ma, Zhenqiang; Kats, Mikhail A.; Zhu, Jia; Ooi, Boon S.; Gan, Qiaoqiang; Yu, Zongfu (Proceedings of the National Academy of Sciences, Proceedings of the National Academy of Sciences, 2021-03-31) [Article]
      A radiative vapor condenser sheds heat in the form of infrared radiation and cools itself to below the ambient air temperature to produce liquid water from vapor. This effect has been known for centuries, and is exploited by some insects to survive in dry deserts. Humans have also been using radiative condensation for dew collection. However, all existing radiative vapor condensers must operate during the nighttime. Here, we develop daytime radiative condensers that continue to operate 24 h a day. These daytime radiative condensers can produce water from vapor under direct sunlight, without active consumption of energy. Combined with traditional passive cooling via convection and conduction, radiative cooling can substantially increase the performance of passive vapor condensation, which can be used for passive water extraction and purification technologies.
    • InGaN-based nanowires development for energy harvesting and conversion applications

      Zhang, Huafan; Min, Jung-Wook; Gnanasekar, Paulraj; Ng, Tien Khee; Ooi, Boon S. (Journal of Applied Physics, AIP Publishing, 2021-03-28) [Article]
      This Tutorial teaches the essential development of nitrogen-plasma-assisted molecular-beam-epitaxy grown InGaN nanowires as an application-inspired platform for energy harvesting and conversion applications by growing dislocation- and strain-relieved axial InGaN-based nanowires. The Tutorial aims to shed light on the interfacial, surface, electrical, and photoelectrochemical characteristics of InGaN nanowires through nanoscale and ultrafast characterizations. Understanding the interrelated optical-physical properties proved critical in the development of renewable-energy harvesting and energy conversion devices. Benefiting from their unique aspect ratio and surface-to-volume ratio, semiconductor properties, and piezoelectric properties, the group-III-nitride nanowires, especially InGaN nanowires, are promising for clean energy conversion applications, including piezotronic/piezo-phototronic and solar-to-clean-fuel energy-conversion.
    • Engineering Band-Type Alignment in CsPbBr 3 Perovskite-Based Artificial Multiple Quantum Wells

      Lee, Kwangjae; Merdad, Noor A.; Maity, Partha; El Demellawi, Jehad K.; Lui, Zhixiong; Sinatra, Lutfan; Zhumekenov, Ayan A.; Hedhili, Mohamed N.; Min, Jung-Wook; Min, Jung-Hong; Gutierrez Arzaluz, Luis; Anjum, Dalaver H.; Wei, Nini; Ooi, Boon S.; Alshareef, Husam N.; Mohammed, Omar F.; Bakr, Osman (Advanced Materials, Wiley, 2021-03-24) [Article]
      Semiconductor heterostructures of multiple quantum wells (MQWs) have major applications in optoelectronics. However, for halide perovskites—the leading class of emerging semiconductors—building a variety of bandgap alignments (i.e., band-types) in MQWs is not yet realized owing to the limitations of the current set of used barrier materials. Here, artificial perovskite-based MQWs using 2,2′,2″-(1,3,5-benzinetriyl)-tris(1-phenyl-1-H-benzimidazole), tris-(8-hydroxyquinoline)aluminum, and 2,9-dimethyl-4,7-diphenyl-1,10-phenanthroline as quantum barrier materials are introduced. The structures of three different five-stacked perovskite-based MQWs each exhibiting a different band offset with CsPbBr3 in the conduction and valence bands, resulting in a variety of MQW band alignments, i.e., type-I or type-II structures, are shown. Transient absorption spectroscopy reveals the disparity in charge carrier dynamics between type-I and type-II MQWs. Photodiodes of each type of perovskite artificial MQWs show entirely different carrier behaviors and photoresponse characteristics. Compared with bulk perovskite devices, type-II MQW photodiodes demonstrate a more than tenfold increase in the rectification ratio. The findings open new opportunities for producing halide-perovskite-based quantum devices by bandgap engineering using simple quantum barrier considerations.
    • Toward Large-Scale Ga2O3 Membranes via Quasi-Van Der Waals Epitaxy on Epitaxial Graphene Layers

      Min, Jung-Hong; Li, Kuang-Hui; Kim, Yong-Hyeon; Min, Jungwook; Kang, Chun Hong; Kim, Kyoung-Ho; Lee, Jae-Seong; Lee, Kwang Jae; Jeong, Seong-Min; Lee, Dong-Seon; Bae, Si-Young; Ng, Tien Khee; Ooi, Boon S. (ACS Applied Materials & Interfaces, American Chemical Society (ACS), 2021-03-12) [Article]
      Epitaxial growth using graphene (GR), weakly bonded by van der Waals force, is a subject of interest for fabricating technologically important semiconductor membranes. Such membranes can potentially offer effective cooling and dimensional scale-down for high voltage power devices and deep ultraviolet optoelectronics at a fraction of the bulk-device cost. Here, we report on a large-area β-Ga<sub>2</sub>O<sub>3</sub> nanomembrane spontaneous-exfoliation (1 cm × 1 cm) from layers of compressive-strained epitaxial graphene (EG) grown on SiC, and demonstrated high-responsivity flexible solar-blind photodetectors. The EG was favorably influenced by lattice arrangement of SiC, and thus enabled β-Ga<sub>2</sub>O<sub>3</sub> direct-epitaxy on the EG. The β-Ga<sub>2</sub>O<sub>3</sub> layer was spontaneously exfoliated at the interface of GR owing to its low interfacial toughness by controlling the energy release rate through electroplated Ni layers. The use of GR templates contributes to the seamless exfoliation of the nanomembranes, and the technique is relevant to eventual nanomembrane-based integrated device technology.
    • Towards Detecting Red Palm Weevil Using Machine Learning and Fiber Optic Distributed Acoustic Sensing

      Wang, Biwei; Mao, Yuan; Ashry, Islam; Al-Fehaid, Yousef; Al-Shawaf, Abdulmoneim; Ng, Tien Khee; Yu, Changyuan; Ooi, Boon S. (Sensors, MDPI AG, 2021-02-25) [Article]
      Red palm weevil (RPW) is a detrimental pest, which has wiped out many palm tree farms worldwide. Early detection of RPW is challenging, especially in large-scale farms. Here, we introduce the combination of machine learning and fiber optic distributed acoustic sensing (DAS) techniques as a solution for the early detection of RPW in vast farms. Within the laboratory environment, we reconstructed the conditions of a farm that includes an infested tree with ∼12 day old weevil larvae and another healthy tree. Meanwhile, some noise sources are introduced, including wind and bird sounds around the trees. After training with the experimental time- and frequency-domain data provided by the fiber optic DAS system, a fully-connected artificial neural network (ANN) and a convolutional neural network (CNN) can efficiently recognize the healthy and infested trees with high classification accuracy values (99.9% by ANN with temporal data and 99.7% by CNN with spectral data, in reasonable noise conditions). This work paves the way for deploying the high efficiency and cost-effective fiber optic DAS to monitor RPW in open-air and large-scale farms containing thousands of trees.
    • Ultra-thin dark amorphous TiOx hollow nanotubes for full spectrum solar energy harvesting and conversion‡

      Liu, Youhai; Song, Haomin; Bei, Zongmin; Zhou, Lyu; Zhao, Chao; Ooi, Boon S.; Gan, Qiaoqiang (Nano Energy, Elsevier BV, 2021-02-15) [Article]
      Dark titania (TiOx) have been widely used for solar energy harvesting and conversion applications due to its excellent light absorbing performance throughout the ultraviolet to near infrared wavelength band, low cost, and non-toxic nature. However, the synthesis methods of dark TiOx are usually complicated and time-consuming. Here we report a facile and rapid method to fabricate dark amorphous TiOx (am-TiOx) hollow nanotube arrays on nanoporous anodic alumina oxide (AAO) templates using atomic layer deposition. Systematic investigation was performed to demonstrate that Ti3+ and O- species in the am-TiOx ultra-thin films, as well as the spatial distribution of these am-TiOx ultra-thin films on the vertical side walls of AAO templates are two major mechanisms of the black color. Importantly, the film deposition took ~18 min only to produce the optimized ~4-nm-thick am-TiOx film. Representative applications were demonstrated using photocatalytic reduction of silver nitrate and photothermal solar vapor generation, revealing the potential of these ultra-thin dark am-TiOx/AAO structures for full spectrum solar energy harvesting and conversion.
    • Domain-Size-Dependent Residual Stress Governs the Phase-Transition and Photoluminescence Behavior of Methylammonium Lead Iodide

      Lee, Kwangjae; Turedi, Bekir; Giugni, Andrea; Lintangpradipto, Muhammad Naufal; Zhumekenov, Ayan A.; Alsalloum, Abdullah; Min, Jung-Hong; Dursun, Ibrahim; Naphade, Rounak; Mitra, Somak; Roqan, Iman S.; Ooi, Boon S.; Mohammed, Omar F.; Di Fabrizio, Enzo M.; Cho, Namchul; Bakr, Osman (Advanced Functional Materials, Wiley, 2021-02-11) [Article]
      Methylammonium lead iodide (MAPbI3) perovskite has garnered significant interest as a versatile material for optoelectronic applications. The temperature-dependent photoluminescence (TDPL) and phase-transition behaviors revealed in previous studies have become standard indicators of defects, stability, charge carrier dynamics, and device performance. However, published reports abound with examples of irregular photoluminescence and phase-transition phenomena that are difficult to reconcile, posing major challenges in the correlation of those properties with the actual material state or with the subsequent device performance. In this paper, a unifying explanation for the seemingly inconsistent TDPL and phase-transition (orthorhombic-to-tetragonal) characteristics observed for MAPbI3 is presented. By investigating MAPbI3 perovskites with varying crystalline states, ranging from polycrystal to highly oriented crystal as well as single-crystals, key features in the TDPL and phase-transition behaviors are identified that are related to the extent of crystal domain-size-dependent residual stress and stem from the considerable volume difference (ΔV ≈ 4.5%) between the primitive unit cells of the orthorhombic (at 80 K) and tetragonal phases (at 300 K) of MAPbI3. This fundamental connection is essential for understanding the photophysics and material processing of soft perovskites.
    • Hybrid concentrated radiative cooling and solar heating in a single system

      Zhou, Lyu; Song, Haomin; Zhang, Nan; Rada, Jacob; Singer, Matthew; Zhang, Huafan; Ooi, Boon S.; Yu, Zongfu; Gan, Qiaoqiang (Cell Reports Physical Science, Elsevier BV, 2021-02) [Article]
      Radiative cooling is an emerging sustainable technology that does not require electricity to function. However, to realize sub-ambient cooling, the effects of the undesired incident solar energy must be minimized. Considering an ideal blackbody radiator at 300 K, the maximum cooling power density is 160 W/m2. Here, we report an architecture capable of overcoming this challenge by using two spectrally selective mirrors to simultaneously absorb the incident sunlight and re-direct the thermal emission from a vertically aligned emitter. With this configuration, both sides of the vertical emitter can be used together to realize a measured local cooling power density of over 270 W/m2 in a controlled laboratory environment. Under standard atmospheric pressure, we realized cooling that was 14C below the ambient temperature in the laboratory environment and a more than 12C temperature reduction in outdoor testing.
    • Theory and practice of orbital angular momentum and beyond

      Trichili, Abderrahmen; Cox, Mitchell A.; Perez-Garcia, Benjamin; Ooi, Boon S.; Alouini, Mohamed-Slim (Accepted by Wiley, 2021-02) [Book Chapter]
      Nearly three decades since its discovery, orbital angular momentum (OAM) has proven to be highly versatile for a wide range of applications. It is an indispensable tool in quantum optics, has made a significant impact in optical tweezing, enabled higher contrast and more detailed imaging, and offers a convenient way to harness the space degree of freedom in telecommunications. In this paper, we present a review of a wide range of applications of OAM as well as describing the creation and detection of OAM modes, with a focus on the use of OAM in communications. In addition, we detail various similar higher-order optical modes, such as vector vortex modes, and provide an introduction to the use of OAM in quantum optics, pitched for readers new to the field.
    • Group-III-nitride and halide-perovskite semiconductor gain media for amplified spontaneous emission and lasing applications

      Ng, Tien Khee; Holguin Lerma, Jorge Alberto; Kang, Chun Hong; Ashry, Islam; Zhang, Huafan; Bucci, Giada; Ooi, Boon S. (Journal of Physics D: Applied Physics, IOP Publishing, 2021-01-22) [Article]
      Group-III-nitride optical devices are conventionally important for displays and solid-state lighting, and recently have garnered much interest in the field of visible-light communication. While visible-light laser technology has become mature, developing a range of compact, small footprint, high optical power components for the green-yellow gap wavelengths still requires material development and device design breakthroughs, as well as hybrid integration of materials to overcome the limitations of conventional approaches. The present review focuses on the development of laser and amplified spontaneous emission (ASE) devices in the visible wavelength regime using primarily group-III-nitride and halide-perovskite semiconductors, which are at disparate stages of maturity. While the former is well established in the violet-blue-green operating wavelength regime, the latter, which is capable of solution-based processing and wavelength-tunability in the green-yellow-red regime, promises easy heterogeneous integration to form a new class of hybrid semiconductor light emitters. Prospects for the use of perovskite in ASE and lasing applications are discussed in the context of facile fabrication techniques and promising wavelength-tunable light-emitting device applications, as well as the potential integration with group-III-nitride contact and distributed Bragg reflector layers, which is promising as a future research direction. The absence of lattice-matching limitations, and the presence of direct bandgaps and excellent carrier transport in halide-perovskite semiconductors, are both encouraging and thought-provoking for device researchers who seek to explore new possibilities either experimentally or theoretically. These combined properties inspire researchers who seek to examine the suitability of such materials for potential novel electrical injection devices designed for targeted applications related to lasing and operating-wavelength tuning.
    • Colloidal PbS quantum dots for visible-to-near-infrared optical-internet-of-things

      Tankimanova, Aigerim; Kang, Chun Hong; Alkhazragi, Omar; Tang, Haodong; Kong, Meiwei; Sinatra, Lutfan; Lutfullin, Marat; Li, Depeng; Ding, Shihao; Xu, Bing; Bakr, Osman; Wang, Kai; Sun, Xiao Wei; Ng, Tien Khee; Ooi, Boon S. (Institute of Electrical and Electronics Engineers (IEEE), 2021) [Article]
      The emergence of optical-internet-of-things (Optical-IoT) for sixth-generation (6G) network has been envisaged to relieve the bandwidth congestion in the conventional radio frequency (RF) channel, and to support the ever-increasing number of smart devices. Among the plethora of device-innovation deemed essential for fortifying the development, herein we report on the visible-to-near-infrared color-conversion luminescent-dyes based on lead sulphide quantum dots (PbS QDs), so as to achieve an eye-safe high-speed optical link. The solution-processed PbS QDs exhibited strong absorption in the visible range, radiative recombination lifetime of 6.4 s, as well as high photoluminescence quantum yield of up to 88%. Our proof-of-principle demonstration based on an orthogonal frequency-division multiplexing (OFDM) modulation scheme established an infrared data transmission of 0.27 Mbit/s, readily supporting an indoor optical-IoT system, and shed light on the possibility for PbS-integrated transceivers in supporting remote access control of multiple nodes. We further envisaged that our investigations could find applications in future development of solution-processable PbS-integrated luminescent fibers, concentrators, and waveguides for high-speed optical receivers.
    • Performance Characterization of High and Low Power Prism based Tunable Blue Laser Diodes Systems

      Mukhtar, Sani; Holguin Lerma, Jorge Alberto; Ashry, Islam; Ng, Tien Khee; Ooi, Boon S.; Khan, M. Z. M. (Institute of Electrical and Electronics Engineers (IEEE), 2020-11-13) [Conference Paper]
      Comparison of high- and low-power tunable external-cavity blue laser-diode system demonstrates a tunability of 10.6 and 4nm, respectively, with a corresponding SMSR as high as 35 and 32dB and linewidth as low as 97 and 59pm, while showcasing high stability at extreme operating conditions.
    • A highly sensitive, large area, and self-powered UV photodetector based on coalesced gallium nitride nanorods/graphene/silicon (111) heterostructure

      Zulkifli, Nur 'Adnin Akmar; Park, Kwangwook; Min, Jung-Wook; Ooi, Boon S.; Zakaria, Rozalina; Kim, Jongmin; Tan, Chee Leong (Applied Physics Letters, AIP Publishing, 2020-11-13) [Article]
      In this paper, we demonstrate an ultraviolet photodetector (UV-PD) that uses coalesced gallium nitride (GaN) nanorods (NRs) on a graphene/Si (111) substrate grown by plasma-assisted molecular beam epitaxy. We report a highly sensitive, self-powered, and hybrid GaN NR/graphene/Si (111) PD with a relatively large 100 mm2 active area, a high responsivity of 17.4 A/W, a high specific detectivity of 1.23 1013 Jones, and fast response speeds of 13.2/13.7 ls (20 kHz) under a UV light of 355 nm at zero bias voltage. The results show that the thin graphene acts as a perfect interface for GaN NRs, encouraging growth with minimum defects on the Si substrate. Our results suggest that the GaN NR/graphene/Si (111) heterojunction has a range of interesting properties that make it well-suited for a variety of photodetection applications.
    • Large-Scale Sub-1-nm Random Gaps Approaching the Quantum Upper Limit for Quantitative Chemical Sensing

      Zhang, Nan; Hu, Haifeng; Singer, Matthew; Li, Kuang-Hui; Zhou, Lyu; Ooi, Boon S.; Gan, Qiaoqiang (Advanced Optical Materials, Wiley, 2020-10-27) [Article]
      Metallic nanostructures with nanogap features can confine electromagnetic fields into extremely small volumes. In particular, as the gap size is scaled down to sub-nanometer regime, the quantum effects for localized field enhancement reveal the ultimate capability for light–matter interaction. Although the enhancement factor approaching the quantum upper limit has been reported, the grand challenge for surface-enhanced vibrational spectroscopic sensing remains in the inherent randomness, preventing uniformly distributed localized fields over large areas. Herein, a strategy to fabricate high-density random metallic nanopatterns with accurately controlled nanogaps, defined by atomic-layer-deposition and self-assembled-monolayer processes, is reported. As the gap size approaches the quantum regime of ≈0.78 nm, its potential for quantitative sensing, based on a record-high uniformity with the relative standard deviation of 4.3% over a large area of 22 mm × 60 mm, is demonstrated. This superior feature paves the way towards more affordable and quantitative sensing using quantum-limit-approaching nanogap structures.
    • Survey of energy-autonomous solar cell receivers for satellite–air–ground–ocean optical wireless communication

      Kong, Meiwei; Kang, Chun Hong; Alkhazragi, Omar; Sun, Xiaobin; Guo, Yujian; Sait, Mohammed; Holguin Lerma, Jorge Alberto; Ng, Tien Khee; Ooi, Boon S. (Progress in Quantum Electronics, Elsevier BV, 2020-10-14) [Article]
      With the advent of the Internet of Things, energy- and bandwidth-related issues are becoming increasingly prominent in the context of supporting the massive connectivity of various smart devices. To this end, we propose that solar cells with the dual functions of energy harvesting and signal acquisition are critical for alleviating energy-related issues and enabling optical wireless communication (OWC) across the satellite–air–ground–ocean (SAGO) boundaries. Moreover, we present the first comprehensive survey on solar cell-based OWC technology. First, the historical evolution of this technology is summarized, from its beginnings to recent advances, to provide the relative merits of a variety of solar cells for simultaneous energy harvesting and OWC in different application scenarios. Second, the performance metrics, circuit design, and architectural design for energy-autonomous solar cell receivers are provided to help understand the basic principles of this technology. Finally, with a view to its future application to SAGO communication networks, we note the challenges and future trends of research related to this technology in terms of channel characterization, light source development, photodetector development, modulation and multiplexing techniques, and network implementations.
    • Diffused-Line-of-Sight Communication for Mobile and Fixed Underwater Nodes

      Guo, Yujian; Kong, Meiwei; Alkhazragi, Omar; Sun, Xiaobin; Sait, Mohammed; Ng, Tien Khee; Ooi, Boon S. (IEEE Photonics Journal, Institute of Electrical and Electronics Engineers (IEEE), 2020-10-13) [Article]
      The misalignment of mobile underwater wireless optical communication (UWOC) systems, compounded by misalignment in underwater mobility scenarios, is a practical problem that can be resolved through various means. This work describes a pulse-position modulation (PPM) based diffused-line-of-sight UWOC system that offers a solution to this issue. PPM is found to be power-efficient and, in terms of bit error ratio performances, outperforms on-off keying modulation and orthogonal frequency-division multiplexing modulation in complex dynamic underwater channels. Through indoor experiments and an outdoor deployment, herein, we validated the robustness of our PPM-based mobile UWOC system. This work is expected to shed light on practical implementation of UWOC network for relieving the strict positioning-acquisition-and-tracking requirements when underwater apparatus is transmitting or receiving signals on-the-fly.
    • Nanoporous GaN/n-type GaN: a cathode structure for ITO-free perovskite solar cells

      Lee, Kwangjae; Min, Jung-Wook; Turedi, Bekir; Alsalloum, Abdullah Yousef; Min, Jung-Hong; Kim, Yeong Jae; Yoo, Young Jin; Oh, Semi; Cho, Namchul; Subedi, Ram Chandra; Mitra, Somak; Yoon, Sang Eun; Kim, Jong Hyun; Park, Kwangwook; Chung, Tae-Hoon; Jung, Sung Hoon; Baek, Jong-Hyeob; Song, Young Min; Roqan, Iman S.; Ng, Tien Khee; Ooi, Boon S.; Bakr, Osman (ACS Energy Letters, American Chemical Society (ACS), 2020-09-17) [Article]
      Introducing suitable electron/hole transport layers and transparent conductive layers (TCLs) into perovskite solar cells (PSCs) is key to enhancing the selective extraction of charge carriers and reducing surface recombination losses. Here, we introduce nanoporous gallium nitride (NP GaN)/n-type GaN (n-GaN) as a dual-function cathode structure for PSCs, acting as both the TCL and the electron transport layer (ETL). We demonstrate that the hierarchical NP GaN structure provides an expanded interfacial contact area with the perovskite absorber, while the n-GaN under the NP GaN displays high transmittance in the visible spectrum as well as higher lateral electric conductivity than that of a conventional ITO film. Prototype MAPbI3 PSCs based on this NP GaN/n-GaN cathode structure (without an extra ETL) show a power conversion efficiency of up to 18.79%. The NP GaN/n-GaN platform demonstrated herein paves the way for PSCs to take advantage of the widely available heterostructures of mature III-nitride-based technologies.
    • 1.5-Gbit/s Filter-free Optical Communication Link based on Wavelength-selective Semipolar ($20\overline{21}$) InGaN/GaN Micro-photodetector

      Kang, Chun Hong; Liu, Guangyu; Lee, Changmin; Alkhazragi, Omar; Wagstaff, Jonathan M.; Li, Kuang-Hui; Alhawaj, Fatimah; Ng, Tien Khee; Speck, James S.; Nakamura, Shuji; DenBaars, Steven P.; Ooi, Boon S. (The Optical Society, 2020-09-14) [Conference Paper]
      We report on wavelength-selective semipolar (2021) InGaN/GaN micro-photodetector with broad modulation bandwidth of 293.52 MHz, outperforming polar-based devices. A 1.5-Gbit/s data rate was achieved without the need of spectral-efficient modulation format.
    • Single/Multi-wavelength green laser diode system

      Shamim, Md. Hosne Mobarok; Ng, Tien Khee; Ooi, Boon S.; Khan, Mohammed Zahed Mustafa (The Optical SocietyIEEE, 2020-09-11) [Conference Paper]
      Single and two-stage self-injection locking in InGaN/GaN laser diode is presented. Near single-mode emission with 34pm linewidth, and simultaneous locking of four longitudinal modes with appreciable 18dB SMSR and <2.5dB peak power ratio is achieved.