https://www.microprobesystem.com Hello, Welcome to Nextron! 넥스트론은 독특하고 소형한 프로브 시스템, 환경컨트롤러를 포함한 연구장비 개발 및 제조 전문 기업입니다. 넥스트론은 독창적인 디자인, 첨단 소형화 기술, 높은 성능, 맞춤형 솔루션 제공을 통해 차별화됩니다. Key Products로는 Ultra-miniature Piezo Modules, Micro probe system, Gas Sensing system, MFC(Mass Flow Controller) Gas Controller, Vacuum Pressure Controller, Humidity Controller, Temperature Controller 이 있습니다. 넥스트론의 주요 고객은 반도체 제조업체,디스플레이 제조업체,전자 부품 제조업체,연구 기관,대학교로 전 대륙의 수많은 국가에서 이미 넥스트론의 제품을 사용하고 있습니다. Hello, Welcome to Nextron! Nextron specializes in developing and manufacturing research equipment, including unique and compact probe systems and environmental controllers. Nextron differentiates itself by providing unique design, advanced miniaturization technology, high performance, and customized solutions. Key products include Ultra-miniature Piezo Modules, Micro probe system, Gas Sensing system, MFC (Mass Flow Controller) Gas Controller, Vacuum Pressure Controller, Humidity Controller, and Temperature Controller. Nextron's main customers are semiconductor manufacturers, display manufacturers, electronic component manufacturers, research institutes, and universities, and many countries across all continents are already using Nextron's products. https://www.microprobesystem.com/intro.html Compact Size, Optimized for in-situ measurement, Unique Probing System Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/system.html Small is powerful! Gas Sensor Measurement System (GSS) Gas Flow Control Specification • Small size for compact set-up: 324 x 233 x h170 mm • Two options of control range: GSS-PT(10 ~ 200 °C) / GSS-CHL(RT ~ 450 °C) • High accuracy of mass flow control (±0.4 % of reading and ±0.2 % of full scale) • Various gas selection: 150+ gases including corrosive ones 20 settings of mixed gas Mass flow 500 SCCM Single gas Standard 128 selectable gas such as Air, N2, Ar, H2, ... Mixed gas Corrosive 32 selectable gas such as NH3, Cl2, NO, ... 20 defintable gas mixes (possibly up to 5 gases with 0.01 % composition resolution) In-situ Stretching Probe System Specification • Effective stroke: 10 ~ 60 mm • Max sample width: 30 mm • Max stretching speed: 10 mm/s • Cycle repeatability: 10 μm • Max tensile force: 3 kg • Force meter resolution: 5 gf • Probing contact force: 5 ~ 20 gf • Electrical measurements: 2 or 4 wire measurements (500VDC/1A) Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/chamber.html Design your lab's efficiency with unique Micro Probe System! Piezo-Driven probe Ultra compact piezo module Modue Speed Stroke (X , Y axis) Stroke (Z - axis) Holding Force Manipulate Dimension Resolution Chamber size • Temp. Range 5 mm /s 8 mm 3 mm 250 gf ~ 300 gf 20 x 20 x 30 mm 1 μm Ø 230 x 50 mm • CH (RT ~ +1000 °C) • PT (-40 ~ +200 °C) • LN (80 K ~ RT) In-situ Raman Battery Test Cell Ultra compact piezo module In-situ Raman battery cell is capable of measuring the Raman spectrum of the cross-section of a battery sample. The In-situ Raman battery cell is developed for the in-situ study of the interface between layers such as anode, cathode, and separator. It is available to measure in-situ Raman not only liquid electrolyte batteries but also solid-state batteries. The product has a feature that can easily inject a liquid electrolyte and simple preparation of test samples. The Vertical Raman Electrochemical Reactor Cell Ultra compact piezo module Customizable with materials and structures that can be used in the chemical field. For in-situ XRD Measurements Ultra compact piezo module • Apply electric field • Control temperature • Control vacuum/gas Probe Head Chamber equipped with Pogo Pin Ultra compact piezo module Custom-made Probe Head • No. of Pins • Position of Pins • Shape of Probe head • Size of Sample Stage Optical window stage chamber for integrated electro-optical experiments SPM (scanning probe microscopy) Thermal Stage Ultra compact piezo module Max temp. Normal operating temp Max heating /Cooling Rate Accuracy Stage Size Stage material 200 °C 20 °C ~ 150 °C 30 °C/min 0.1 °C Ø 18 mm Au coated Cu Peltier type sample stage The system features an active cooling system that maintains the same heating and cooling rates. Temp. Sample stage size Stage material -40 ~ +200 °C 19 x 19 mm Rhodium coated copper Peltier type sample stage with hole Experiments such as transmittance measurements are possible through the hole. Temp. Sample stage size Stage material -40 ~ +170 °C 16 x 16 mm Rhodium coated copper Ceramic heater sample stage The equipment is capable of measuring without a cooling unit for one hour at 450 °C. Temp. Sample stage size Stage material RT ~ +450 °C Ø 1/2 inch Alumina sample stageCeramic heater sample stage Temp. Sample stage size Stage material RT ~ +750 °C / RT ~ +1000 °C Ø 1/2 inch AlN Nitrogen sample stage Temp. Sample stage size Stage material 80 K ~ RT Ø 14 mm Cu sample stage. 13-Channel Micro Probe System, 10-Channel Micro Probe System, For LCC Chip carrier The stage is a leadless chip carrier socket, it is possible to mount the LCC chip carrier and conduct experiments under various environmental changes.6 Probe and 24 Pin Terminal Block Customization is possible with various probe methods and various probe combinations.RF Micro Probe System with GSG Probe MAX frequency 40GHz. Dual Stage Model For applications such as the Seebeck effect. Micro Probe System for Field Emission Measurements A slidable top anode and the metal stage are connected to the SMA feedthrough. 4 probes connectable to the device.Temperature Probe TC probe makes it possible to easily and quickly measure the temperature of a desired point. Gas Sensor Analysis System It is combined with Humidity Control System, MFC Gas Control Stage, Sourcemeter, Vaccum Pump and Integrated Software.MPS with Ready to Mount Treaded Hole The threaded holes allow mounting with the most preferred stage shape. Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/controller.html Unique research tools create multiple possibilities! MFC Gas Control Stage Gas Flow Control •The Ultimate Solution for Precise and Stable Flow Control The BMGC –XX Gas Flow Station, built with the mass flow control unit, gas flow pipeline, and electrical components, is the ideal solution for various applications demanding precise and stable flow control. •Ultra compact flow controllers Smallest footprint dimension, 86(L) x 130(W) x 142(H) mm Reduction of wetted surfaces and residual gas •Ease of Use Ready for operation with just a few gas lines and a USB connection. Precision Pressure Control System Pressure Control Range • Range-option : 0.001 ~ 1000 Torr The Precision Vacuum Pressure control system can control partial pressure with the desire gas by adjusting the flow. The software can automatically acquest and maintain it as a recipe. Humidity Control System The Precision Humidity Control System Precise PID control Humidity sensor is installed inside the MPS chambers Normal ramp speed: 10 %RH/min. Normal range: 4~95%RH* =*Ranges may differ depending on experimentation and laboratory temperature. Temperature Controller All micro probe stations are capable of precise temperature control. In the case of the Peltier model, active cooling is possible, and in particular, it has the advantage of special temperature profiles such as cycle tests. The LN model has a built-in LN circulation pump for low-temperature cooling. Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/option.html Solution for Electric, Dielectric, Magnetic and Optical Measurement! A UNIQUE PROBE MODULE Our outstanding probe module makes you experience amazing and convenient probing. Rh Wire Probe Tip Tip dia.: 250 μm Max operating temp.: 1000 °C Great durability at high temperature Tungsten Probe Tip Tip dia.: 50 μm, 100 μm Max operating temp.: 450 °C Plate: None or Rh Standard Optical Cover Window: sapphire 0.43 T Apature: Ø 17 mm EM Light Shielding Cap for Standard Optical Cover Gas Shower Head Type Cover for Fast Gas Responsiveness Metal mesh outlet Gas Shower Head Type Cover for Fast Gas Responsiveness Standard Swagelok type inlet Cover for Microscope Objective Turret 2 Inch Viewport Window External XYZ Micro positioner module Stable contact is possible up to a 200μm contact pad when using an external position option. Optical Breadboard Convenient mount with digital microscope and External XYZ Micro Positioner Module. 350 x 350 mm only 2.3 kg metric or imperial type. Polymer Capacitance Measurement Fixture Polymer Fixture equipped on the Peltier Stage useful to measure the dielectric property of a polymer film. Especially, the reliability of the measurement can be improved as it can give a constant contact-pressure by one probe module. Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/application.html Nextron RD team is ready to discuss your complex needs! In-situ observation of structural- and resistance-changes by redox reactions • XRD chamber: Nextron XRD Micro Probe System • Sample: SrFe0.8Co0.2O2.5 on 001 SrTiO3 • Beam line: Pohang Accelerator Laboratory 3D beam line • Measurement: Real-time XRD and resistance measurements in supply of N2 (2.5 hrs), O2 (6 hrs), and N2 (2.5 hrs) in sequence. Flow rate was 20 sccm. • Results: The lattice constant of SrFe0.8Co0.2O2.5 thin film shifted sequentially to 3.99 Å (N2), 3.90 Å (O2), and 4.00 Å (N2). Associated resistance changes is observed due to topotactic transformations. This research work is supported by 'Busan Open Laboratory Business Meeting Market Demands' project. Hydrogen gas sensor ACS Sens. 2021, 6, 4145−4155 Hydrogen Gas Sensor ACS Sens. 2021, 6, 4145−4155 Figure. Integrated in-plane microheater’s (a) temperature variations in terms of the applied DC bias voltages, (b) repeatability at 180 °C, (c) sensitivity and linearity, and (d) surface temperature analysis by a thermal imaging camera at 8 V DC bias. Resistive gas sensor characterization Measured while purging hydrogen and nitrogen mixed gas without using vacuum pump Sample: Palladium coated Zinc oxide(ZnO/Al2O3) nanowire for hydrogen gas sensing. Raman mapping This data was contributed by Nextron's partner, Weve. Micro Probe System is perfectly compatible with Weve's products. Raman Spectrometry Vanadium dioxide(VO2) nanowire Study of phase transition by temperature. Photocurrent mapping. Optical transmittance of VO2 thermochromic films Materials and Design 182 (2019) 107970 Figure. Transmittance hysteresis curves at wavelength of 2000 nmfor (a) thermal and (b) IPL sintered VO2 films. The temperature corresponding to themaximumof first-order derivative curves for (c) thermal and (d) IPL sintered VO2 films. Light-emitting diodes Nanoscale, 2019, 11, 18444–18448 Figure. Temperature-dependent I–V characteristics for (a) the reference LED and (b) the self-protective LED under pulse operation. Piezoresistive Pressure Sensor Sensors and Actuators A 314 (2020) 112217 The bridge voltage as function of pressure after an offset voltage correction at 100 kPa. The Wheatstone bridges connections to the SMU; schematically (left) and through microscope (right). Thermal resonant frequency measurement This data was contributed by Nextron’s partner, Polytec GmbH. Micro Probe System is used for Polytec’s products as their environmental chamber. Electromigration test J. Phys.: Condens. Matter 34 (2022) 175401 Figure (a) Top view of the sample used in electromigration test. (b) A schematic overview of the electromigration measurement setup. Figure. Electromigration results for 300 °C-deposited Al stripes under 1 MA cm−2 at 200 °C, 250 °C, 300 °C, and 350 °C at 10 h. MIT (Metal-Insulator Transition) Single crystalline VO2 nanobeams Study of MIT (Metal-Insulator Transition) Rapid Microfluidic PCR (Polymerase Chain Reaction) Slide glass substrate Denaturation at 94 °C and annealing/extension at 59 °C. Other Applications • Gas sensor characterization • Rapid Microfluidic PCR (Polymerase Chain Reaction) • Photovoltaic cells’ and thermoelectric materials’ characterization • Transistors, diodes, LED, ... testing • Bulk and thin film materials’ thermal conductivity measurements (3-ω Method) • Phase transition materials’ electrical/optical characterization (metal oxides, Memristor,…) • Characterization of MEMS/NEMS mechanical and electro- mechanical resonators(reference clocks, mass sensors) • Characterization of micro-coils and micro-antenna for inductive sensors(Impedance spectroscopy of biological tissues, In vivo RMN) • Capacitive, resistive resonant micro/nano sensors testing Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/customers.html u.s air force, UCLA, nebraska, Northeastern University, Stanford University, The Ohio state University, The University of UTAH, University at Buffalo, Sandia National Laboratories, AMETEK, University of Rlorida, Massachusetts Insitute of Technology, MIT, Caltech, University of Maryland, University of Pittsburgh, Simon fraser University, Ecole de Technologie Superieure, ETS, Argonne National Laboratory, Binghamton University, State University of NewYork, University of Michigan, Apple, Purdue University, University of Missouri, UTEP, Canada NRC CNRC, University of Central Florida, PennState University, Yale, Arizona State University, Kansas State University, Fraunhofer IPMS, Polytec, TU Delft, ESIEE paris, University of Oxford, Universite Paris Cite, IFSTTAR, LMGP, Ecole Polytecnnique, Universite Paris SUD. FCT, Faculdade de ciencias tecnologia, C2N, Universite Paris-est, CentraleSupelec, Universitat Jaume-I, National Research Tomsk State University, RAM Group, Uninova, Universite Polytechnique Hauts-de-france, ICAM, Alma materstudiorum Universita di Bologna, European Space Agency, Ioffe Insitute, Rzhanov Institute of Semiconductor Physics, VTT, Centralelille, SAL, Silicon Austria Labs, Université de Picardie Jules Verne, UPJV,nstitut Matériaux Microélectronique Nanosciences de Provence, IM2NP, Université Toulouse III - Paul Sabatier, University College Cork, University of Tartu, Universidad Zaragoza, Politecnica, Luxembourg Institute of Science and Technology, LIST, Aalto-yliopisto, Foundation for Research and Technology, UCL, MAScIR - Moroccan Foundation for Advanced Science, Innovation and Research | Université Mohammed VI Polytechnique, University of Crete, Vector Technologies, Grenoble INP, University of Cambridge, Universite of Montrellier, l'insitut d' electronique, University of Eastern Finland, Universidad de Malaga, INSA, Institut National des Sciences Appliquée Lyon,Instituto de Tecnologia QUIMICA Instituto Italiano di techologia Apel Laser INFLPR Institut Catala de Nanociencia i Nanotecnologia (ICN2R) Centro Nacional de Microlelctronica (CNM) The French Alternative Energies and Atomic Energy Commission(CEA) Graphenea Imperial College London Institute for Microelectronics and Microsystems(IMM) iMT Max-Planck-Institut für Intelligente Systeme Heidelberg University Centre national de la recherche scientifique (CNRS) CNR Istituto di Struttura della Materia Aix Marseille Université Socialement engagée HZDR | Helmholtz-Zentrum Dresden-Rossendorf Politecnico di Torino Leibniz Institute of Surface Engineering e.V. (IOM) photonlines social opticas university of zagreb University of Valencia Indian Institute of Technology Guwahati MIMOS, National RD Centre in ICT Malaysia, SIMIT,University of Science and Technology of China, METU, Huazhong University of Science and Technology, Shaanxi Normal University, Chula, Chulaongkorn University, Pehnikaa University, Cense, Centre for nano science and engineering, Koc University, KAUST, Tsinghua University, Westlake University, The University of Tokyo, Ben-gurion University of the Negev, Tehchnology Innovation Institue, Fudan University, Toyota, City University of Hong Kong, National Cheng Kung University, Keio University, AIST, Shanghai Jiao Tong University, IPT ALMAT Postech, DGIST, KAIST, GIST, UNIST, Kookmin University, 국민대학교, Yonsei University, 연세대학교, Inha University, Ajou University인하대학교, 아주대학교, Gachon University, 가천대학교, Pusna University, 부산대학교, dongguk University, 동국대학교, Yeungnam University, 영남대학교, KIST, Kyungpook National University, Jeju National University, ETRI, KIT, Korea Institute of Technology, KIMS, Korea Insititute of Meterial Science, Korea Basic Science Institute, KRICT, KITECH, National Nonofab Center, KERI, LG화학, 쏠락, 한양대학교, Hanyang University, Seoul national University, sogang University, Hongik University, Jeonbuk University, Wonkwang University, Changwon University, Andong National University, Korea Electronics Technology Institue, Hankyoung National University, Samsung, Pukyong National University, Samyang Chemical Co., Ltd., KAERI, Korea Atomic Energy Research Institute, WithMems, GiEVER, Soongsil University, Dong-Eui University, Chonnam National University, Korea Aerospace University, Korea University, Seoul National Univ of Science Technology, Chungnam National University, Gyeongsang National University, 서울대학교, 서강대학교, 홍익대학교, 한국표준과학연구원, 전북대학교, 원광대학교, 창원대학교, 국립안동대학교, 한국전자기술연구원, 한국세라믹기술원, 국립한경대학교, 삼성종합기술원, 국립부경대학교, 삼양화학공업, 한국원자력연구원, 숭실대학교, 동의대학교, 전남대학교, 제주대학교, 한국항공대학교, 고려대학교, 서울과학기술대학교, 충남대학교, 경상국립대학교, 한국기초과학지원연구원, 한국화학연구원, 한국생산기술연구원, 나노종합기술원, 한국전기연구원 Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/aboutus.html About us Hello, welcome to NEXTRON. Since its founding in 2007, NEXTRON has progressed in its development of researcher-centered research equipment of the highest value. Recently, it grafted temperature/vacuum/measurement technology onto subminiature design technique to develop proprietary systems such as the Micro Vacuum Probe System and RTP system and its pushing towards its entry into the global market. With the pride and sense of vocation that we are able to contribute in even the smallest way towards executing NEXTRON’s vision, “Science and technology that coexists with nature and humanity,” we will do our very best to become a global, professional research equipment company. We sincerely ask for the continuous attention and love of many researchers as we proceed into the future. Thank you. Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/publications.html Zhen Cui, Yaqian Zhang, Dong Hu, Sten Vollebregt, Jiajie Fan, Xuejun Fan and Guoqi Zhang “Effects of temperature and grain size on diffusivity of aluminium: electromigration experiment and molecular dynamic simulation.” J. Phys. Condens. Matter 34,175401(2022). Sihyeok Kim, Gurpreet Singh, Mintaek oh, and Keekeun Lee “An Analysis of a Highly Sensitive and Selective Hydrogen Gas Sensor Based on a 3D Cu-Doped SnO2 Sensing Material by Efficient Electronic Sensor Interface.” ACS Sens. 6,4145-4155 (2021). Paul Grey, Manuel Chapa, Miguel Alexandre, Tiago Mateus, Elvira Fortunato, Rodrigo Martins, Manuel J. Mendes, Luís Pereira “Combining Soft with Hard Condensed Matter for Circular Polarized Light Sensing and Logic Operations.” Adv. Opt. Mater. 9,2001731(2021). Nor Syahira Mohd Tombel Siti Aishah Mohamad Badaruddin; Firzalaila Syarina Md Yakin; Hasan Firdaus Mohd Zaki; Mohd Ismahadi Syono, “Detection of low PPM of volatile organic compounds using nanomaterial functionalized reduced graphene oxide sensor.” AIP Conf Proc 2368, 20004 (2021). Taejung Kim, Seungwook Lee, Wootaek Cho, Yeong Min Kwon, Jeong Min Baik and Heungjoo Shin, “Development of a Novel Gas-Sensing Platform Based on a Network of Metal Oxide Nanowire Junctions Formed on a Suspended Carbon Nanomesh Backbone.” Sensors 21, 4525 (2021). Jung-Hun Lee, Ji-Soo Kim, Hyun-Joong Kim, Kyujong Park, Jungwoo Moon, Jinyoung Lee and Youngju Park “Free Volume Effect via Various Chemical Structured Monomers on Adhesion Property and Relative Permittivity in Acrylic Pressure Sensitive Adhesives.” Polymers 12, 2633 (2020). Aleksei Almaev, Vladimir Nikolaev, Pavel Butenko, Sergey Stepanov, Aleksei Pechnikov, Nikita Yakovlev, Igor Sinyugin, Sevastian Shapenkov, Mikhail Scheglov “Gas Sensors Based on Pseudohexagonal Phase of Gallium Oxide.” Phys Status Solidi B Basic Res 259, 2100306 (2022). Mohammad Moein Mohammadi, Abhishek Kumar, Jun Liu, Yang Liu, Thomas Thundat, and Mark T. Swihart “Hydrogen Sensing at Room Temperature Using Flame-Synthesized Palladium-Decorated Crumpled Reduced Graphene Oxide Nanocomposites.” ACS Sens. 5, 2344-2350 (2020). Seyoung Park, Soo-Min Lee, Jin-Kyo Jeong, Donggu Kim, Hyunsoo Kim, Hyun-Sook Lee, Wooyoung Lee “Sensing performance of Pd nanogap supported on an elastomeric substrate in a wide temperature range of –40 to 70 °C.” Sens. Actuators B Chem. 348, 130716 (2021). Shuvra Mondal, Bok Ki Min, Yoonsik Yi, and Choon-Gi Choi “Highly Sensitive and Fast Responsive Humidity Sensor based in 2D PtSe2 with Gamma Radiation Tolerance.” Adv. Mater. Technol. 7, 2100751 (2022). Seung Bae Son, Ji Won Youn, Kwang-Seok Kim, Dae Up Kim “Optical properties of periodic micropatterned VO2 thermochromic films prepared by thermal and intense pulsed light sintering.” Mater. Des. 182, 107970 (2019). Jianwen Sun, Dong Hu, Zewen Liu, Luke M. Middelburg, Sten Vollebregt, Pasqualina M. Sarro, Guoqi Zhang “Low power AlGaN/GaN MEMS pressure sensor for high vacuum application.” Sens. Actuator A Phys. 314, 112217 (2020). Osbel Almor, Gebhard J. Matt, Albert These, Andrii Kanak, Ievgen Levchuk, Shreetu Shrestha, Andres Osvet, Christoph J. Brabec, and Germà Garcia-Belmonte “Surface versus Bulk Currents and Ionic Space-Charge Effects in CsPbBr3 Single Crystals.” . Phys. Chem. Lett. 13, 824-3830 2022). Mohd Faizol Abdullah, Nur Julia Nazim Bulya Nazim, Nurhidaya Soriadi, Siti Aishah Mohamad Badaruddin, Mohd Rofei Mat Hussin, Mohd Ismahadi Syono “Thermal Characterization of Multi-Layer Graphene Heat Spreader by Pt/Cu/Ti Micro-Coil.” PHYS STATUS SOLIDI A 218, 2100301 (2021). Jong Won Lee, Jeonghyeon Park, Heera Kwon, Woong-Ki Hong, Jong Kyu Kima and Jaehee Cho “Self-protective GaInN-based light-emitting diodes with VO2 nanowires†.” Nanoscale 11, 18444-18448 (2019). Luke M. Middelburg, H. W. van Zeijl, Sten Vollebreg,; Bruno Morana, Guoqi Zhang, ”Toward a Self-Sensing Piezoresistive Pressure Sensor for All-SiC Monolithic Integration.” IEEE Sens. J. 20, 11265-11274 (2020). Shuvra Mondal, Seong Jun Kim, and Choon-Gi Choi “Honeycomb-like MoS2 Nanotube Array- Based Wearable Sensors for Noninvasive Detection of Human Skin Moisture. “ ACS Appl. Mater. Interfaces 12, 17029-17038 (2020). Murat Onen, Nicolas Emond, Ju Li, Bilge Yildiz, and Jesús A. del Alamo “CMOS-Compatible Protonic Programmable Resistor Based on Phosphosilicate Glass Electrolyte for Analog Deep Learning.“ Nano Lett. 21, 6111-6116 (2021). Jiarui Mo, Luke M. Middelburg, Bruno Morana, H. W. van Zeijl, Sten Vollebregt, Guoqi Zhang “Surface-Micromachined Silicon Carbide Pirani Gauges for Harsh Environments.” IEEE Sens. J. 21, 1350-1358 (2020). Taejung Kim, Wootaek Cho, Beomsang Kim, Junyeong Yeom, Yeong Min Kwon, Jeong Min Baik, Jae Joon Kim, Heungjoo Shin “Batch Nanofabrication of Suspended Single 1D Nanoheaters for Ultralow-Power Metal Oxide Semiconductor-Based Gas Sensors.” Small 18, 2204078 (2022). Yiyang Li, Elliot J. Fuller, Shiva Asapu, Sapan Agarwal, Tomochika Kurita, J. Joshua Yang, and A. Alec Talin “Low-Voltage, CMOS-Free Synaptic Memory Based on LiXTiO2 Redox Transistors.” ACS Appl. Mater. Interfaces 11, 38982-38992 (2019). Wen Sui, Haoran Wang, Jaesung Lee, Afzaal Qamar, Mina Rais-Zadeh, Philip X.-L. Feng “AlScN-on-SiC Thin Film Micromachined Resonant Transducers Operating in High- Temperature Environment up to 600 °C.” Adv. Funct. Mater. 32, 2202204 (2022). Yiyang Li, Elliot J. Fuller, Joshua D. Sugar, Sangmin Yoo, David S. Ashby, Christopher H. Bennett, Robert D. Horton, Michael S. Bartsch, Matthew J. Marinella, Wei D. Lu, A. Alec Talin “Filament-Free Bulk Resistive Memory Enables Deterministic Analogue Switching.” Adv. Mater. 32, 2003984 (2020). A.V. Almaev, V.I. Nikolaev, N.N. Yakovlev, P.N. Butenko, S.I. Stepanov, A.I. Pechnikov, M.P. Scheglov, E.V. Chernikov “Hydrogen sensors based on Pt/α-Ga2O3:Sn/Pt structures.” Sens. Actuators B Chem. 364, 131904 (2022). Yiyang Li, Jorik van de Groep, A. Alec Talin, and Mark L. Brongersma “Dynamic Tuning of Gap Plasmon Resonances Using a Solid-State Electrochromic Device.” Nano Lett. 19, 7988- 7995 (2019). Alexander Stangl, Adeel Riaz, Laetitia Rapenne, José Manuel Caicedo, Juan de Dios Sirvent, Federico Baiutti, Carmen Jiménez, Albert Tarancón, Michel Mermoux and Mónica Burriel ”Tailored nano-columnar La2NiO4 cathodes for improved electrode performance†‡.” J. Mater. Chem. A 10,2528-2540 (2022). Yusin Pak, Yeonggyo Jeong, Naresh Alaal, Hyeonghun Kim, Jeonghoon Chae, Jung-Wook Min, Assa Aravindh Sasikala Devi, Somak Mitra, Da Hoon Lee, Yogeenth Kumaresan, Woojin Park, Tae-Wook Kim, Iman S. Roqan, Gun-Young Jung “Highly Stable and Ultrafast Hydrogen Gas Sensor Based on 15 nm Nanogaps Switching in a Palladium–Gold Nanoribbons Array.” Adv. Mater. Interfaces 6, 1801442 (2019). Diana S. Kim, Virgil J. Watkins, Laszlo A. Cline, Jingxian Li, Kai Sun, Joshua D. Sugar, Elliot J. Fuller, A. Alec Talin, Yiyang Li ”Nonvolatile Electrochemical Random-Access Memory under Short Circuit.” Adv. Electron. Mater. 9, 2200958 (2023). Y. Pak, Y. Kim, N. Lim, J.-W. Min, W. Park, W. Kim, Y. Jeong, H. Kim, K. Kim, S. Mitra, B. Xin, T.- W. Kim, I. S. Roqan, B. Cho, G.-Y. Jung “Scalable integration of periodically aligned 2D-MoS2 nanoribbon array.“ APL Mater. 6, 76102 (2018). Hyeonghun Kim, Woochul Kim, Jiyoon Park, Namsoo Lim, Ryeri Lee, Sung Jun Cho, Yogeenth Kumaresan, Myoung-Kyu Oh and Gun Young Jung, “Surface conversion of ZnO nanorods to ZIF-8 to suppress surface defects for a visible-blind UV photodetector†.” Nanoscale 10, 21168-21177 (2018). M. Rahimi, K. Sobnath, F. Mallet, P. Lafarge, C. Barraud, W. Daney de Marcillac, D. Fournier, and M.L. Della Rocca “Complete Determination of Thermoelectric and Thermal Properties of Supported Few-Layer Two-Dimensional Materials.” Phys. Rev. Appl. 19, 34075 (2023). Alexander Stangl, Dolors Pla, Caroline Pirovano, Odette Chaix-Pluchery, Federico Baiutti, Francesco Chiabrera, Albert Tarancón, Carmen Jiménez, Michel Mermoux, Mónica Burriel “Isotope Exchange Raman Spectroscopy (IERS): a novel technique to probe physicochemical processes in situ” Advanced Materials, 2303259 (2023). 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Geon Gug Yang, Dong-Ha Kim, Sanket Samal, Jungwoo Choi, Heejung Roh, Camille E. Cunin, Hyuck Mo Lee, Sang Ouk Kim, Mircea Dincă, Aristide Gumyusenge “Polymer-Based Thermally Stable Chemiresistive Sensor for Real-Time Monitoring of NO2 Gas Emission”ACS sensors, 8.10: 3687-3692.(2023) Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/exhibition.html • 2024 SSI24 in London • 2024 SEMICON West in San Francisco • 2024 KIEEME ANNUAL SUMMER CONFERENCE in Busan • 2024 EMCDRC in College Park • 2024 ICSM 24 in Dresden • 2024 IEEE Sensors France Workshop in Grenoble • 2024 KMS Summer Conference in Jeju • 2024 EMRS Spring in Strasbourg • 2024 ECS in San Francisco • 2024 I2MTC in Glasgow • 2024 KPS Spring Meeting in Daejeon • 2024 MRS Spring in Seattle • 2024 MEMS Engineer Forum in Tokyo • 2024 KECS Spring in Busan • ASCoF Spring Meeting in Bordeaux • 2024 ITC in Daejeon • 2024 APS in Minneapolis • The 19th Busan Dielectric Symposium • 2024 MEMS in Austin • ICAMD in Jeju • 2023 MRS Fall in Boston • S3IC2023 in Barcelona • MNS in Yeosu • PRICM11 in Jeju • ICAE 2023 in Jeju • IEEE Sensors in Vienna • 2023 KPS Fall in Changwon • 2023 KCERS Fall Meeting in Seoul • IWOE29 in Busan • ECS in Gothenburg • E-MRS 2023 in Warsaw • Eurosensors 2023 in Lecce • IMC20 2023 in Bexco • 2023 K-GOW in Yeosu • DXC 2023 in Lombard • KSEA 2023 in Dallas • AEFM 2023 in Seoul • SCES 2023 in Incheon • EMC DRC 2023 in Santa Barbara • Transducers 2023 in Kyoto • KEEME Annual Summer Conference in Pyeonchang • APNFO14 2023 in Busan • FMS 2023 in Busan • 2023 GCIM in Jeju • 2023 E-MRS in Strasburg • 2023 ECS w SOFC in Boston • 2023 DTIP in Malta • 2023 I2MTC in Kuala Lumpur • 2023 ICMCTF in San Diego • 2023 IEEE NEMS in Jeju • 2023 SMSI 2023 in Nuremberg • 2023 KIM Spring Meeting in Jeju • 2023 KPS Spring Meeting in Daejeon • 2023 KCERS Spring Meeting in Jeju • 2023 MRS Spring in San Francisco • 2023 KECS Spring Meeting in Jeju • 2023 KMEMS in Jeju • 2023 APS in Las Vegas • 2023 KCS in Jungsun • 2023 ICEIC in Singapore • 2023 The 18th Busan Dielectric Symposium • 2023 MEMS in Muchini • 2022 MRS Fall in Boston • 2022 K-MRS in Jeju • 2022 ENGE in Jeju • 2022 KPS in Busan • 2022 E-MRS in Warsaw • 2022 ICORS in California • 2022 EKC in Marseille • 2022 SSI in Boston • 2022 DRC EMC in Columbus • 2022 MRS Spring in Hawaii Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/exhibition_pic%202022.html 2022 MRS Fall in Boston, MA, USA 2022 K-MRS in Jeju, Korea ENGE 2022 in Jeju, Korea 2022 KPS in Busan, Korea 2022 E-MRS in Warsaw, Poland 2022 ICORS in Long Beach, CA, USA 2022 EKC in Marseille, France 2022 SSI in Boston, MA, USA 2022 DRC EMC in Columbus, OH, USA 2022 MRS Spring in Hawaii, HI, USA Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/exhibition_pic%202023.html PRICM11, Jeju, Korea 2023 IEEE Sensors, Vienna, Austira 2023 ECS, Gothenburg, Sweden 2023 E-MRS in Warsaw, Poland 2023 KSEA in Dallas, TX, USA 2023 AEFM in Seoul, Korea 2023 SCES in Incheon, Korea 2023 EMC DRC in Santa Barbara, CA, USA 2023 ECS w SOFC in Boston, MA, USA 2023 ICMCTF in San Diego, CA, USA 2023 SMSI in Nuremberg, Germany 2023 KPS Spring Meeting in Daejeon, Korea 2023 Spring Meeting of the Korean Ceramic Socity in Jeju, Korea 2023 MRS Spring in San Francisco, CA 2023 Spring Meeting Academic Presentaion of the Korean Electrochemical Society in Jeju, Korea 2023 Korean Conference on Semiconductor in Jungsun, Korea 2023 ICEIC in Singapore The 18th Busan Dielectric Symposium in Busan, Korea Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/exhibition_pic%202024.html 2024 KIEEME ANNUAL SUMMER CONFERENCE in Busan, Korea 2024 EMCDRC in College Park, MD 2024 EMRS Spring in Strasbourg, France 2024 ECS in San Francisco, CA 2024 I2MTC in Glasgow, Scotland 2024 MRS Spring in Seattle, WA 2024 MEMS Engineer Forum in Tokyo, Japan 2024 MEMS in Austin, Texas Tue, 16 Jul 2024 06:18:00 GMT https://www.microprobesystem.com/contact.html Contact * Name * Email your.name@email.com * Application XRD, RAMAN, Gas sensing * Inflow route search exhibit advertisement recommend Message Customizing (ex. Dual Peltier, Field Emission) Micro Probe System - Main Chamber Selection Guide Probe Type Motorized(Piezo) Manual(Tracking) Motorized Manual For the contact pad smaller than 250μm x 250μm, Motorized (Piezo) type probe is recommended. Frequency DC (0 ~ 300MHz) RF ( ~ 40GHz) Channel 4CH 6CH 8CH LLCC OTHER Temperature 80 K ~ RT -40 °C ~ 200 °C RT ~ 450 °C RT ~ 750 °C RT ~ 1000 °C Controller Temperature Humidity MFC (Gas Flow) Vacuum Pressure Piezo Software MFC (Gas Flow) Gas Option *How many types of gas will flow at the same time? ex. 3 *MFC Specification for Gas Sensor Application GAS Concentration Gas cylinder *Balancing gas N2,Air 100 % *Target gas Gas1 1 ~ 100 %,ppm,ppb Gas2 1 ~ 100 %,ppm,ppb Gas3 1 ~ 100 %,ppm,ppb Gas4 1 ~ 100 %,ppm,ppb Gas5 1 ~ 100 %,ppm,ppb Send Head Office Korea sales@nextron.co.kr +82 51 512 6770 Overseas Branch Office Europe Paris, France ykkim@nextron.co.kr America Chicago, USA dhkim@nextron.co.kr Japan MTT Instruments, Inc., Osaka t.fukushima@mtt-ins.co.jp China www.miniprobesystem.com 18802935517@163.com Tue, 16 Jul 2024 06:18:00 GMT