Review Articles
  • Deep-ultraviolet integrated photonic and optoelectronic devices: A prospect of the hybridization of group III–nitrides, III–oxides, and two-dimensional materials

    Nasir Alfaraj, Jung-Wook Min, Chun Hong Kang, Abdullah A. Alatawi, Davide Priante, Ram Chandra Subedi, Malleswararao Tangi, Tien Khee Ng, Boon S. Ooi

    J. Semicond.  2019, 40 (12): 121801

    doi: 10.1088/1674-4926/40/12/121801

    Abstract Full Text PDF Get Citation

    Progress in the design and fabrication of ultraviolet and deep-ultraviolet group III–nitride optoelectronic devices, based on aluminum gallium nitride and boron nitride and their alloys, and the heterogeneous integration with two-dimensional and oxide-based materials is reviewed. We emphasize wide-bandgap nitride compound semiconductors (i.e., (B, Al, Ga)N) as the deep-ultraviolet materials of interest, and two-dimensional materials, namely graphene, two-dimensional boron nitride, and two-dimensional transition metal dichalcogenides, along with gallium oxide, as the hybrid integrated materials. We examine their crystallographic properties and elaborate on the challenges that hinder the realization of efficient and reliable ultraviolet and deep-ultraviolet devices. In this article we provide an overview of aluminum nitride, sapphire, and gallium oxide as platforms for deep-ultraviolet optoelectronic devices, in which we criticize the status of sapphire as a platform for efficient deep-ultraviolet devices and detail advancements in device growth and fabrication on aluminum nitride and gallium oxide substrates. A critical review of the current status of deep-ultraviolet light emission and detection materials and devices is provided.

  • Recent progress of SiC UV single photon counting avalanche photodiodes

    Linlin Su, Dong Zhou, Hai Lu, Rong Zhang, Youdou Zheng

    J. Semicond.  2019, 40 (12): 121802

    doi: 10.1088/1674-4926/40/12/121802

    Abstract Full Text PDF Get Citation

    4H-SiC single photon counting avalanche photodiodes (SPADs) are prior devices for weak ultraviolet (UV) signal detection with the advantages of small size, low leakage current, high avalanche multiplication gain, and high quantum efficiency, which benefit from the large bandgap energy, high carrier drift velocity and excellent physical stability of 4H-SiC semiconductor material. UV detectors are widely used in many key applications, such as missile plume detection, corona discharge, UV astronomy, and biological and chemical agent detection. In this paper, we will describe basic concepts and review recent results on device design, process development, and basic characterizations of 4H-SiC avalanche photodiodes. Several promising device structures and uniformity of avalanche multiplication are discussed, which are important for achieving high performance of 4H-SiC UV SPADs.

  • The fabrication of AlN by hydride vapor phase epitaxy

    Maosong Sun, Jinfeng Li, Jicai Zhang, Wenhong Sun

    J. Semicond.  2019, 40 (12): 121803

    doi: 10.1088/1674-4926/40/12/121803

    Abstract Full Text PDF Get Citation

    Aluminum nitride (AlN) is the promising substrates material for the epitaxial growth of III-nitrides devices, such as high-power, high-frequency electronic, deep ultraviolet optoelectronics and acoustic devices. However, it is rather difficult to obtain the high quality and crack-free thick AlN wafers because of the low surface migration of Al adatoms and the large thermal and lattice mismatches between the foreign substrates and AlN. In this work, the fabrication of AlN material by hydride vapor phase epitaxy (HVPE) was summarized and discussed. At last, the outlook of the production of AlN by HVPE was prospected.

  • Smart gas sensor arrays powered by artificial intelligence

    Zhesi Chen, Zhuo Chen, Zhilong Song, Wenhao Ye, Zhiyong Fan

    J. Semicond.  2019, 40 (11): 111601

    doi: 10.1088/1674-4926/40/11/111601

    Abstract Full Text PDF Get Citation

    Mobile robots behaving as humans should possess multifunctional flexible sensing systems including vision, hearing, touch, smell, and taste. A gas sensor array (GSA), also known as electronic nose, is a possible solution for a robotic olfactory system that can detect and discriminate a wide variety of gas molecules. Artificial intelligence (AI) applied to an electronic nose involves a diverse set of machine learning algorithms which can generate a smell print by analyzing the signal pattern from the GSA. A combination of GSA and AI algorithms can empower intelligent robots with great capabilities in many areas such as environmental monitoring, gas leakage detection, food and beverage production and storage, and especially disease diagnosis through detection of different types and concentrations of target gases with the advantages of portability, low-power-consumption and ease-of-operation. It is exciting to envisage robots equipped with a "nose" acting as family doctor who will guard every family member's health and keep their home safe. In this review, we give a summary of the state-of the-art research progress in the fabrication techniques for GSAs and typical algorithms employed in artificial olfactory systems, exploring their potential applications in disease diagnosis, environmental monitoring, and explosive detection. We also discuss the key limitations of gas sensor units and their possible solutions. Finally, we present the outlook of GSAs over the horizon of smart homes and cities.

  • Recent advances in flexible photodetectors based on 1D nanostructures

    Senpo Yip, Lifan Shen, Johnny C Ho

    J. Semicond.  2019, 40 (11): 111602

    doi: 10.1088/1674-4926/40/11/111602

    Abstract Full Text PDF Get Citation

    Semiconductor nanowires have demonstrated excellent electronic and optoelectronic properties. When integrated into photodetectors, excellent device performance can be easily attained. Apart from the exceptional performance, these nanowires can also enable robust and mechanically flexible photodetectors for various advanced utilizations that the rigid counterparts cannot perform. These unique applications include personal healthcare, next-generation robotics and many others. In this review, we would first discuss the nanowire fabrication techniques as well as the assembly methods of constructing large-scale nanowire arrays. Then, the recent development of flexible photodetectors based on these different nanowire material systems is evaluated in detail. At the same time, we also introduce some recent advancement that allows individual photodetectors to integrate into a more complex system for advanced deployment. Finally, a short conclusion and outlook of challenges faced in the future of the community is presented.

  • Electrospun flexible sensor

    Qi Liu, Seeram Ramakrishna, Yun-Ze Long

    J. Semicond.  2019, 40 (11): 111603

    doi: 10.1088/1674-4926/40/11/111603

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    Flexible sensors have received wide attention because of their ability to adapt to a variety of complex environments. Electrospinning technology has significant advantages in the preparation of flexible sensors. This paper summarizes the progress in the preparation of flexible sensors by electrospinning. Sensors that respond to light, stress, and gas are presented separately. Finally, some directions for electrospinning and flexible sensors are discussed.

  • Flexible and stretchable photodetectors and gas sensors for wearable healthcare based on solution-processable metal chalcogenides

    Qi Yan, Liang Gao, Jiang Tang, Huan Liu

    J. Semicond.  2019, 40 (11): 111604

    doi: 10.1088/1674-4926/40/11/111604

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    Wearable smart sensors are considered to be the new generation of personal portable devices for health monitoring. By attaching to the skin surface, these sensors are closely related to body signals (such as heart rate, blood oxygen saturation, breath markers, etc.) and ambient signals (such as ultraviolet radiation, inflammable and explosive, toxic and harmful gases), thus providing new opportunities for human activity monitoring and personal telemedicine care. Here we focus on photodetectors and gas sensors built from metal chalcogenide, which have made great progress in recent years. Firstly, we present an overview of healthcare applications based on photodetectors and gas sensors, and discuss the requirement associated with these applications in detail. We then discuss advantages and properties of solution-processable metal chalcogenides, followed by some recent achievements in health monitoring with photodetectors and gas sensors based on metal chalcogenides. Last we present further research directions and challenges to develop an integrated wearable platform for monitoring human activity and personal healthcare.

  • Recent advances in lithographic fabrication of micro-/nanostructured polydimethylsiloxanes and their soft electronic applications

    Donghwi Cho, Junyong Park, Taehoon Kim, Seokwoo Jeon

    J. Semicond.  2019, 40 (11): 111605

    doi: 10.1088/1674-4926/40/11/111605

    Abstract Full Text PDF Get Citation

    The intensive development of micro-/nanotechnologies offers a new route to construct sophisticated architectures of emerging soft electronics. Among the many classes of stretchable materials, micro-/nanostructured poly(dimethylsiloxane) (PDMS) has emerged as a vital building block based on its merits of flexibility, stretchability, simple processing, and, more importantly, high degrees of freedom of incorporation with other functional materials, including metals and semiconductors. The artificially designed geometries play important roles in achieving the desired mechanical and electrical performances of devices and thus show great potential for applications in the fields of stretchable displays, sensors and actuators as well as in health-monitoring device platforms. Meanwhile, novel lithographic methods to produce stretchable platforms with superb reliability have recently attracted research interest. The aim of this review is to comprehensively summarize the progress regarding micro-/nanostructured PDMS and their promising soft electronic applications. This review is concluded with a brief outlook and further research directions.

  • Preparation and application of carbon nanotubes flexible sensors

    Shuo Li, Xiao Feng, Hao Liu, Kai Wang, Yun-Ze Long, S. Ramakrishna

    J. Semicond.  2019, 40 (11): 111606

    doi: 10.1088/1674-4926/40/11/111606

    Abstract Full Text PDF Get Citation

    Based on the good extensibility and conductivity, the flexible sensors (FSs) have a wide range of applications in the field of the electrochemical energy storage and variable stress sensors, which causes that the preparation of FSs also become a hot spot of research. Among the materials for preparing the FSs, the flexible carbon matrix composites (FCMCs) have become the widely used material since the good performance in the properties of electrochemistry and mechanics, which could be divided into three types: the carbon nanofibers (CNFs), the carbon nanospheres (CNSs) and the carbon nanotubes (CNTs). Compared with CNFs and CNSs, the CNTs wrapped by the polydimethylsiloxane (PDMS) have the advantages of the excellent extensibility and electrochemical stability. Therefore, the CNTs flexible sensor (CFS) could be well used in the field of the FSs. The purpose of this review is summarizing the preparation methods and application fields of CFS and proposing the research direction of CFS in the future. In this paper, two methods for fabricating the CFS have been designed by consulting the methods mentioned in the literature in recent years, and the advantages and disadvantages between the two methods have been explained. The application fields of CFS in recent years are enumerated, and the conclusion that the application fields of CFS are very wide is drawn. At the end of this paper, the review concludes with an overview of key remaining challenges in the application fields of the CFS.

  • Advances in flexible and wearable pH sensors for wound healing monitoring

    Mei Qin, Hao Guo, Zhang Dai, Xu Yan, Xin Ning

    J. Semicond.  2019, 40 (11): 111607

    doi: 10.1088/1674-4926/40/11/111607

    Abstract Full Text PDF Get Citation

    Wound healing has been recognized as a complex and dynamic regeneration process and attracted increasing interests on its management. For effective wound healing management, a continuous monitoring on the wound healing based on sensors is essential. Since pH has been found to play an important role on wound healing process, a variety of pH sensors systems for wound healing monitoring have been greatly developed in recent years. Among these pH sensors, flexible and wearable pH sensors which can be incorporated with wound dressing have gained much attention. In this review, the recent advances in the development of flexible and wearable pH sensors for wound healing monitoring have been comprehensive summarized from the range of optical and electrochemical bases.

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