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Similar to the way spiders detect vibrations, a new biosensor can detect a range of biosignals, from pulse to breathing ratesWearable sensors are becoming increasingly popular for biomedical applications such as health monitoring. Drawing inspiration from how spiders detect vibrations, researchers from Ajou University in South Korea have developed a sensor that can respond to a wide range of pressures. The sensor is a promising step toward the development of highly sensitive wearable health monitoring devices, allowing the detection of breathing patterns, muscle contractions, and pulse rate fluctuations. Caption: The TUNES sensor detects pressure by mimicking how spiders detect vibrations, allowing for the detection of a wide range of biosignals. The sensor finds use as a highly sensitive wearable sensor for monitoring pulse rates, muscle contractions, and respiration.Picture courtesy: ShutterstockFrom the aircraft wings that were modeled after birds by the Wright brothers, to Japan’s famous bullet train that was inspired by the shape of a kingfisher's beak, mimicking the natural world has often led to breakthroughs that have improved people’s lives drastically.Now, in a study published in npj Flexible Electronics, Associate Professor Daeshik Kang and his research team from Ajou University, South Korea, have added another engineering feat to the list. The team has developed Tunable, Ultrasensitive, Nature-inspired, Epidermal Sensor (TUNES), a biosensing technology that mimics the way spiders detect vibrations. “Flexible devices can sensitively measure physical stimuli such as strain, pressure, and vibrations. However, there is a tradeoff between the sensor's measurement range and sensitivity, requiring different sensors depending on the target signal,” remarks Dr. Kang.Spiders have mechanosensory slit organs present in their legs, used to perceive movements in their environment. These slits contain nerve endings that are activated by vibrations. The unique feature of the slit organs is enabling the spider to adjust the sensitivity by changing the leg position. To detect prey, spiders stretch their legs, opening these slits to enhance sensitivity to smaller vibrations. However, to avoid predators, they bend their legs, compressing or closing the slits in order to only detect large forces.To replicate this, the research team fabricated nanoscale cracks on a metallized polyimide film, mimicking the slits on the spider’s legs. Just the way spiders bend their legs to adjust slit openings, when bent by an external force, the sheet also undergoes changes in the opening of the cracks. This results in a modification to the film's electrical resistance, enabling the detection of a wide range of pressures, from 0.05 Pa–25 kPa.“The TUNES' ability to adjust sensitivity through preset strain overcomes the traditional tradeoff between measurement range and sensitivity,” says Dr. Kang.The sensor’s broad sensitivity to strains makes it extremely versatile in detecting small as well as large mechanical biosignals. For instance, when attached to the ribcage, the sensor responds to the changing volume of the chest cavity during breathing, to monitor respiration. Inspired by this, the research team used the sensor to detect muscle contractions and subtle changes in the pulse rate. They even applied machine learning to the pulse rate data, to automatically identify and diagnose health conditions.These capabilities, explains Dr. Kang, make the sensor highly suitable as a wearable health monitoring system for blood pressure, heart rate, and even age-specific diagnosis. He elaborates, “We anticipate the ability to provide users with the convenience of instantly assessing their health status by measuring various physiological signals using only one sensor system at an affordable cost.”Providing users with the convenience and affordability of instantly assessing their health status by measuring various physiological signals using only one sensor is what drove the team to conduct this research. The highly sensitive sensor allows for non-invasive blood pressure measurements on the wrist, which opens avenues for non-invasive blood pressure monitoring, thus reducing unnecessary surgical risks. What’s more, TUNES has already shown success for non-invasive pressure measurement in clinical trials, proving its practicality, versatility, and effectiveness.We are confident that the team’s efforts will take this valuable biosensor to the masses, sooner rather than later!ReferenceAuthors:Taewi Kim 1, Insic Hong 1, Yeonwook Roh 1, Dongjin Kim1, Sungwook Kim2, Sunghoon Im1, Changhwan Kim 1, Kiwon Jang1, Seongyeon Kim1, Minho Kim1, Jieun Park1, Dohyeon Gong1, Kihyeon Ahn1, Jingoo Lee1, Gunhee Lee3, Hak-Seung Lee4, Jeehoon Kang4, Ji Man Hong5, Seungchul Lee2, Sungchul Seo6, Bon-Kwon Koo 4,7*, Je-sung Koh1*, Seungyong Han 1*, and Daeshik Kang 1*Title of original paper:Spider-inspired tunable mechanosensor for biomedical applicationsJournal:npj Flexible Electronics DOI:10.1038/s41528-023-00247-2 Affiliations:1 Department of Mechanical Engineering, Ajou University, Korea2 Department of Mechanical Engineering, Pohang University of Science and Technology, Korea3 Department of Sustainable Environment Research, Korea Institute of Machinery & Materials, Korea4 Department of Internal Medicine and Cardiovascular Center, SeoulNational University Hospital, Korea5 Department of Neurology and Neurosurgery, Ajou University School of Medicine, Korea6 Department of Nano-chemical, Biological and Environmental Engineering, Seokyeong University, Korea7 Institute on Aging, Seoul National University, Korea*Corresponding authors’ email ids: Daeshik Kang (dskang@ajou.ac.kr); Bon-Kwon Koo (bkkoo@snu.ac.kr); Je-sung Koh (jskoh@ajou.ac.kr); Seungyong Han (sy84han@ajou.ac.kr)About Ajou UniversityFounded in 1973, Ajou University has quickly grown to become one of the top universities in the Republic of Korea. With over 15,000 students and 50 research centers in diverse fields, Ajou University partakes in the largest national research and graduate education project funded by the Korean Ministry of Education. In line with its recently reformed vision, Ajou University’s goal is to change society by connecting minds and carrying out high-impact research to improve the welfare of people in and outside Korea.Website: https://www.ajou.ac.kr/en/index.doAbout Dr. Daeshik Kang from Ajou UniversityDr. Daeshik Kang is an Associate Professor at the Multiscale Bio-inspired Technology (MOST) Lab, Mechanical Engineering Department, Ajou University, South Korea. He received his Ph.D. in Mechanical Engineering from Seoul National University in 2014. After earning his doctorate, he worked as a postdoctoral researcher at the University of Illinois at Urbana-Champaign until 2016. His current research interests include robotics, artificial intelligence-based reinforcement learning, and biomedical applications. He has authored around 60 research papers, which have received close to 5,000 citations.
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- 작성자오동우
- 작성일2023-12-14
- 3268
- 동영상동영상
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Researchers develop a new machine learning algorithm to aid the discovery of new inorganic halide perovskites and their derivatives.A new machine learning-based material discovery algorithm developed by researchers from South Korea explores optical and electrically active inorganic halide perovskite systems and their derivatives, enabling the identification of 153 previously unknown materials. The team has also designed a new metal halide, namely Cs3LuCl6, for white light emission applications. A new machine learning-based algorithm combines basic theoretical concepts with AI technology to detect over 150 new stable compositions of inorganic halide perovskites, including Cs3LuCl6, for white light emission. Picture courtesy: Niethammer Zoltan from Shutterstock.Halide perovskites are photosensitive materials which have taken the world of lasers, light-emitting diodes (LEDs), and solar cells by storm, owing to their excellent optoelectronic properties. Despite their popularity, most organic-inorganic hybrid perovskites suffer from a lack of stability when exposed to environmental factors, such as heat and oxygen. Studies have shown that all-inorganic halide perovskites could be a more resistant-to-degradation alternative to the conventional options. However, the physical and chemical properties of all-inorganic perovskites remain a mystery due to their complex structural features. To overcome this hurdle, a team of researchers led by Assistant Professor Sung Beom Cho from Ajou University in Korea recently combined machine learning with density functional theory (DFT) calculations to computationally screen new inorganic metal halides (especially ones with perovskite structure) and their derivatives. In their study published in ACS Energy Letters on 2 August 2023, they presented a simple AI-powered strategy for investigating structures and properties of metal halides and the synthesis technique for a new perovskite material for white LED applications. “We took case studies of known metal halide systems and merged them with fundamental undergraduate-level theories and the latest in AI technology to transform theoretical concepts into tangible materials,” says Dr. Cho, highlighting the simple yet ingenuine design of the new computational exploration technique. The new workflow enabled exploration of 108 metal halide systems and predicted over 1,700 possible material structures, ranging from 0D to 3D. The team also analyzed the electrical properties and thermal stabilities of possible perovskite structures and mapped the chemical spaces by listing stable compositions on a periodic table. This led to the identification of 153 previously unknown materials. The researchers demonstrated the robustness of their computational analysis by synthesizing Cs3LuCl6, one of the metal halides predicted by the machine learning model. They also tested its optoelectrical properties by using it in white LEDs. Apart from its immediate applications as a tool for discovering newer metal halides with advanced photophysical properties, this work also presents a highly versatile methodology that can revolutionize material discovery and reshape industries dependent on high-performance materials in the long run. “It's a framework that can be extended to virtually any material system, opening a gateway to accelerated discovery in fields crucial to cutting-edge industries like electronics and energy,” concludes Dr. Cho. ReferenceAuthors:Hyeon Woo Kim1,2, Joo Hyeong Han1, Hyunseok Ko2, Tuhin Samanta2, Dong Geon Lee1,2, Dong Won Jeon3,4, Woongchan Kim3,4, Yong-Chae Chung1, Won Bin Im1,*, and Sung Beom Cho3,4,*Title of original paper:High-Throughput Screening on Halide Perovskite Derivatives and Rational Design of Cs3LuCl6Journal:ACS Energy LettersDOI:10.1021/acsenergylett.3c01207 Affiliations:1 Division of Materials Science and Engineering, Hanyang University2 Center of Materials Digitalization, Korea Institute of Ceramic Engineering and Technology (KICET)3 Department of Materials Science and Engineering, Ajou University4 Department of Energy Systems Research, Ajou University*Corresponding authors’ emails: imwonbin@hanyang.ac.kr (Won Bin Im) and csb@ajou.ac.kr (Sung Beom Cho)About Ajou UniversityFounded in 1973, Ajou University has quickly grown to become one of the top universities in the Republic of Korea. With over 15,000 students and 50 research centers in diverse fields, Ajou University partakes in the largest national research and graduate education project funded by the Korean Ministry of Education. In line with its recently reformed vision, Ajou University’s goal is to change society by connecting minds and carrying out high-impact research to improve the welfare of people in and outside Korea. Website: https://www.ajou.ac.kr/en/index.do About the authorDr. Sung Beom Cho has been an Assistant Professor in the Department of Materials Science and Engineering at Ajou University since 2022. He got his Ph.D. in Materials Science and Engineering and dual B.S. degrees in Materials Science Engineering and Physics from Hanyang University. Before joining Ajou University, Dr. Cho was a Senior Researcher at the Korea Institute of Ceramic Engineering and Technology and a Postdoctoral Associate at Washington University in St. Louis. He specializes in multiscale and multiphysics modeling of materials, with a foundation in solid-state physics and thermodynamics. His expertise extends from fundamental research to industrial applications, from semiconductors to batteries.
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- 작성자오동우
- 작성일2023-12-13
- 3112
- 동영상동영상
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Researchers develop bio-inspired capillary-controlled robotic fins for creating displays that consume a fraction of the power used by traditional displaysMorphing appendages allow natural creatures to change their skin color. However, achieving such functionality using traditional light-emitting diodes for soft robots is quite energy-expensive. Now, drawing inspiration from nature, researchers have developed innovative capillary-controlled robotic flapping fins which can be used to fabricate multipixel, ultralow power displays, paving the way for a sustainable future. Creatures like chameleons use morphing appendages to change color. Inspired by this phenomenon, innovative flap-phores can be used to develop multipixel displays that consume thousand times less power than traditional light-emitting diodes.Many creatures in nature are known to have fascinating morphing skins with switchable functions. Chameleons, for instance, masterfully camouflage themselves using pixelated skin appendages. These morphing appendages offer them several advantages, including the ability to change color, temperature, texture, and adhesion properties for camouflage or temperature regulation. Translating these capabilities via soft robotics to curvilinear and soft machines using traditional light-emitting diodes requires considerably higher amount of energy, besides making these devices bulky. Natural creatures, on the other hand, use the flow of liquids to control these appendages, requiring them to expend only a small amount of power. Now, however, drawing inspiration from the capillary bundling of the hair of otters and beetles, an international team of researchers led by Assistant Professor Jonghyun Ha from the Department of Mechanical Engineering at Ajou University, Korea, has developed innovative ultralow power capillary-controlled robotic flapping fins, named “flap4.” Elaborating on the inspiration behind this study, Dr. Ha says, “I was studying how surface tension can deform flexible structures when I had a simple yet intriguing thought. I wondered that if we look at these structures from above, they can be used to change texture or color.” This study was published in Volume 9, Issue 26 of the journal Science Advances on June 30, 2023.The flap4 cells created by the team operate on the principle of capillarity, where a liquid rises or falls in very narrow passages, called capillaries, due to surface tension. The mechanism behind this is similar to that of a sponge with several narrow pores acting as capillaries, allowing it to absorb a large amount of water. Flap4 cells consist of ultrasoft fins fixed to the base of wet cells, which have pores connected to a liquid control system. By controlling the flow rate of the liquid through the pores, capillary action can be used to bend the fin to either narrow or wide side. This innovation allowed the team to develop a soft multipixel display by using each flap4 cell as an individual pixel. Moreover, they also developed an infrared signaling system by using liquids of different temperatures in the flap4 cells. Stressing the importance of this development, Dr. Ha says, “This innovative technology can enable the development of displays that consume 1000-fold less energy than traditional light-emitting diodes for a variety of applications. They can be used to add critical functionalities to soft robots through dynamic skins and even for big signage displays, with substantial power savings.” In summary, this study not only serves as a leap forward in soft robotics but also as an environment-friendly alternative to traditional display technologies. With significantly less energy consumption and reduced electronic waste generation, it paves the way for a sustainable future where technology advancements adapt to the needs of the people and the planet!ReferenceAuthors:Jonghyun Ha1,2, Yun Seong Kim1,3, Chengzhang Li1, Jonghyun Hwang1, Sze Chai Leung1, Ryan Siu1, and Sameh Tawfick1,3,*Title of original paper:Polymorphic display and texture integrated systems controlled by capillarityJournal:Science AdvancesDOI:10.1126/sciadv.adh1321 Affiliations:1Department of Mechanical Science and Engineering, University of Illinois2Department of Mechanical Engineering, Ajou University3The Beckman Institute for Advanced Science and Technology, University of Illinois*Corresponding author’s email: tawfick@illinois.eduAbout Ajou UniversityFounded in 1973, Ajou University has quickly grown to become one of the top universities in the Republic of Korea. With over 15,000 students and 50 research centers in diverse fields, Ajou University partakes in the largest national research and graduate education project funded by the Korean Ministry of Education. In line with its recently reformed vision, Ajou University’s goal is to change society by connecting minds and carrying out high-impact research to improve the welfare of people in and outside Korea. Website: https://www.ajou.ac.kr/en/index.do About the authorJonghyun Ha is currently an Assistant Professor at Ajou University. He earned his B.S. from Chungnam National University in 2012 and Ph.D. from Seoul National University in 2018. He was a postdoc at the University of Illinois at Urbana-Champaign until 2021, after which he joined the Samsung Advanced Institute of Technology. By 2022, he transitioned to his current role at Ajou University. His research interests include microfluidics, porous flows, and microscale fluid-solid interactions. He can be reached by email at: hajh@ajou.ac.kr
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- 작성자오동우
- 작성일2023-12-05
- 2145
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Researchers develop a method for controlling oxygen vacancies in oxides to enhance resistive switching behaviorOxygen vacancies in oxides are often used in memory devices, yet controlling their mechanism proves to be challenging. Now, Korean researchers have come up with a novel method to control the distribution of the oxygen vacancies using electrostatic potential constraints, thereby enhancing the reliability of device performance. This breakthrough potentially paves the way for next-generation memory devices, multi-bit memristors, analog switches, and neuromorphic computing hardware. Researchers have shown that managing oxygen vacancies in transition metal oxide structures allows for consistent resistive switching in memory devices.Oxygen vacancies, which are common functional point defects in various oxides, play a crucial role in memory device technology. This includes "resistive switching devices," which control electrical resistance through the distribution of oxygen vacancies. Given the potential of resistive switching devices for next-generation semiconductor technology, it is crucial to understand the mechanism underlying resistive switching for future advancements of this technology. However, applying this technology is fraught with challenges, particularly in managing the conductance of oxide crystals, resulting in unpredictable and uneven switching behavior.To address these challenges, a team of researchers from Ajou University, Gachon University, and Sejong University has developed a new method for controlling oxygen vacancies in LaAlO3/SrTiO3 (LAO/STO) structures to achieve uniform and consistent resistive switching. Their findings were published in Small on 7 May 2023. Associate Professor Hyungwoo Lee from Ajou University, who led the study, says, “While most studies concentrate on the ‘conducting filament’ mechanism, which relies on a small number of point defects at the filament's edge to influence the overall resistance, switching reliability, and speed, our approach takes a distinct path. Instead of relying on the randomly determined geometry of the conducting filament, we have developed a method that focuses on controlling the density of uniformly distributed point defects across the oxide film.”The team achieved this by imposing electrostatic potential constraints in the LAO/STO structures, ensuring uniform defect distribution and density. This innovative approach reduced the randomness in the movement of the defects and thus provided a solution for reliable performance. Furthermore, evidence of the control of oxygen vacancies was obtained through spectral analysis and Monte–Carlo simulation modeling.While further research is needed for practically applying this approach, the current study demonstrates effective control of oxygen vacancy distribution. By storing information based on defect concentration (similar to biological ionic channels), the switching characteristics of oxide materials can be enhanced. Consequently, this breakthrough paves the way for next-generation memory devices, multi-bit memristors, and analog switching devices, with potential applications in neuromorphic computing hardware as well. “In this regard, our study has opened the door to a future where electronic device technologies based on functional point defects could become a reality,” concludes Dr. Lee.ReferenceAuthors:Jaeyoung Jeon1,2, Kitae Eom3, Minkyung Lee1,2, Sungkyu Kim4, and Hyungwoo Lee1,2,*Title of original paper:Collective Control of Potential-Constrained Oxygen Vacancies in Oxide Heterostructures for Gradual Resistive SwitchingJournal:SmallDOI:10.1002/smll.202301452Affiliations:1Department of Physics, Ajou University2Department of Energy Systems Research, Ajou University3School of Advanced Materials Science and Engineering, Sungkyunkwan University (SKKU) 4Department of Nanotechnology and Advanced Materials Engineering, Sejong University*Corresponding author’s email: hyungwoo@ajou.ac.kr About Ajou UniversityFounded in 1973, Ajou University has quickly grown to become one of the top universities in the Republic of Korea. With over 15,000 students and 50 research centers in diverse fields, Ajou University partakes in the largest national research and graduate education project funded by the Korean Ministry of Education. In line with its recently reformed vision, Ajou University’s goal is to change society by connecting minds and carrying out high-impact research to improve the welfare of people in and outside Korea. Website: https://www.ajou.ac.kr/en/index.do About Associate Professor Hyungwoo Lee Hyungwoo Lee is an Associate Professor at Ajou University, specializing in Physics. His group focuses on designing oxide heterostructures to explore emergent physics. Among his research interests are the 2D electron gas (2DEG) at oxide heterointerfaces, ferroelectric polarizations, exotic magnetisms, superconductivity, and quantum transport properties. Additionally, Dr. Lee's team develops resistive switching devices, ferroelectric tunnel junctions, and quantum devices using atomically-designed oxide heterostructures. Prior to his role at Ajou University, he completed postdoctoral training at Chang-Beom Eom's lab at the University of Wisconsin-Madison and earned a Ph.D. in Physics from Seoul National University in 2013.
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- 작성자오동우
- 작성일2023-12-01
- 1859
- 동영상동영상
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Researchers have now developed semitransparent organic photovoltaic cells with high flexibility and durability for seamless integration into various surfaces. Organic photovoltaics (OPVs) as lightweight, transparent, and thin solar cells are promising for the generation of electricity from sunlight. Such cells can transform surfaces like windows and roofs into self-sustaining power sources. Recently, researchers have made significant strides in enhancing OPVs, making them strain-durable and ultra-flexible. This breakthrough can open the doors to a wide range of applications, including the integration of solar power generation into windows, Internet of Things devices, clothing, and more. Organic photovoltaics (OPVs) are lightweight, transparent, and flexible, making them suitable for seamless and aesthetic integration into various surfaces for electricity generation, including windows and wearable devices. Image courtesy: Lee, Hanbee, et al. "Ultra-flexible semitransparent organic photovoltaics." npj Flexible Electronics 7.1 (2023): 27.Solar energy is undoubtedly an abundant source of energy, but its potential is far from being fully harnessed. Currently, most solar cells are installed in large, flat areas like rooftops or solar farms due to their low flexibility and transparency. An emerging class of transparent, lightweight, ultrathin, and flexible solar cells known as organic photovoltaics (OPVs) is revolutionizing the way in which electricity is generated for powering our daily needs, overcoming the limits of surface area and flexion. These advanced solar cells can be integrated into windows, Internet of Things devices, and even clothing, turning these surfaces into self-sustaining sources of power, with the ability to generate electricity from sunlight.However, they are far from being ideal. There is an intrinsic trade-off between power conversion efficiency (PCE) and average visible transmittance (AVT), which limits the performance of these OPVs. Furthermore, the inherent brittleness of traditional transparent electrodes such as indium tin oxide challenges their durability and makes it difficult to achieve ultra-flexibility, amidst extreme repetitive mechanical stress and optical transparency, simultaneously. Therefore, significant research efforts are underway to overcome these challenges and make the OPVs more durable, efficient, and transparent for advancing their use. Advancing research in this direction, a new study published in npj Flexible Electronics on 3 June 2023 by an international team of researchers led by Assistant Professor Sungjun Park and Associate Professor Jong H. Kim from Ajou University, Republic of Korea, has now proposed OPVs with thinner, ultra-flexible, and semitransparent electrode materials, named “semitransparent organic photovoltaics” (or ST-OPVs). The ST-OPVs proposed in this study have a thickness below two micrometers, are fabricated on a parylene/SU-8 substrate, and utilize an ultrathin silver (Ag) bottom electrode and a dielectric/metal/dielectric (DMD) top electrode. The DMD structure, consisting of molybdenum trioxide (MoO3)/Ag/MoO3 layers, offers excellent optical transparency. Thanks to their nanometer-scale thickness, the ultrathin electrodes impart the proposed OPVs remarkable durability, transparency, and ultra-flexibility. On testing their optical and electrical performance, the OPV devices retained 73% of their initial efficiency after undergoing 1000 compression–release cycles at a compressive strain of 66%. Moreover, the average visible light transmittances remained above 30%. Elaborating further on this, Dr. Kim says, “Notably, the ST-OPVs developed by us achieved a peak PCE of 6.93% and an AVT exceeding 30%, pointing to their high performance. Moreover, to the best of our knowledge, the unprecedented flexibility displayed by these OPVs represents the highest performance reported thus far.” These characteristics make the proposed ST-OPVs suitable for integration into a wide variety of surfaces, without compromising the overall functionality or aesthetics. For instance, they could be utilized for designing windows that are a blend of utility and design and can generate electricity. Moreover, they could be incorporated into wearable devices to serve as a reliable and convenient source of power generation for these devices. “In the long-term, the practical implementation of our devices could significantly enhance energy generation in diverse settings, right from buildings to human bodies. This, in turn, can contribute to the fulfillment of the daily-life energy needs of people while maintaining environmental and personal well-being,” concludes Prof. Park. ReferenceAuthors:Hanbee Lee1, Soyeong Jeong2, Jae-Hyun Kim3, Yong-Ryun Jo4, Hyeong Ju Eun5, Byoungwook Park6, Sung Cheol Yoon6, Jong H. Kim5,*, Seung-Hoon Lee7,*, and Sungjun Park1,3,*Title of original paper:Ultra-flexible semitransparent organic photovoltaicsJournal:npj Flexible Electronics DOI:10.1038/s41528-023-00260-5 Affiliations:1Department of Electrical and Computer Engineering, Ajou University 2Department of Chemistry and Centre for Processable Electronics,Imperial College London3Department of Intelligence Semiconductor Engineering, Ajou University4Advanced Photonics Research Institute (APRI), Gwangju Institute of Science and Technology (GIST)5Department of Molecular Science and Technology, AjouUniversity6Division of Advanced Materials, Korea Research Institute of Chemical Technology (KRICT)7Division of Advanced Materials Engineering, Kongju National University*Corresponding authors’ emails: jonghkim@ajou.ac.kr (Jong H. Kim); leesh23@kongju.ac.kr (Seung-Hoon Lee); sj0223park@ajou.ac.kr (Sungjun Park)About Ajou UniversityFounded in 1973, Ajou University has quickly grown to become one of the top universities in the Republic of Korea. With over 15,000 students and 50 research centers in diverse fields, Ajou University partakes in the largest national research and graduate education project funded by the Korean Ministry of Education. In line with its recently reformed vision, Ajou University’s goal is to change society by connecting minds and carrying out high-impact research to improve the welfare of people in and outside Korea. Website: https://www.ajou.ac.kr/en/index.do About Dr. Sungjun Park and Prof. Jong H. Kim Sungjun Park is an Assistant Professor in the Department of Electrical and Computer Engineering and Jong H. Kim is an Associate Professor in the Department of Molecular Science and Technology at Ajou University, Republic of Korea. Their research focuses on the development of novel solution-processed organic and hybrid optoelectronics materials and soft electronic devices and their integration into wearable sensors and biomedical applications. Dr. Park can be reached by email at sj0223park@ajou.ac.kr, and Dr. Kim can be reached by email at jonghkim@ajou.ac.kr.
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- 작성자오동우
- 작성일2023-10-13
- 1852
- 동영상동영상