• 제목/요약/키워드: SOI membrane

검색결과 15건 처리시간 0.022초

SOI와 트랜치 구조를 이용한 초저소비전력형 미세발열체의 제작과 그 특성 (The Fabrication of Micro-heaters with Low Consumption Power Using SOI and Trench Structures and Its Characteristics)

  • 정귀상;홍석우;이원재;송재성
    • 한국전기전자재료학회논문지
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    • 제14권3호
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    • pp.228-233
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    • 2001
  • This paper presents the optimized design, fabrication and thermal characteristics of micro-heaters for thermal MEMS (micro elelctro mechanical system) applications usign SOI (Si-on-insulator) and trench structures. The micro-heater is based on a thermal measurement principle and contains for thermal isolation regions a 10㎛ thick Si membrane with oxide-filled trenches in the SOI membrane rim. The micro-heater was fabricated with Pt-RTD (resistance thermometer device) on the same substrate by suing MgO as medium layer. The thermal characteristics of the micro-heater wit the SOI membrane is 280$\^{C}$ at input power 0.9W; for the SOI membrane with 10 trenches, it is 580$\^{C}$ due to reduction of the external thermal loss. Therefore, the micro-heater with trenches in SOI membrane rim provides a powerful and versatile alternative technology for improving the performance of micro-thermal sensors and actuators.

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SOI와 드랜치 구조를 이용한 초저소비전력형 미세발열체의 제작 (The fabrication of ultra-low consumption power type micro-heaters using SOI and trenche structures)

  • 정귀상;이종춘;김길중
    • 한국전기전자재료학회:학술대회논문집
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    • 한국전기전자재료학회 2000년도 하계학술대회 논문집
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    • pp.569-572
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    • 2000
  • This paper presents the optimized fabrication and thermal characteristics of micro-heaters for thermal MEMS applications using a SDB SOI substrate. The micro-heater is based on a thermal measurement principle and contains for thermal isolation regions a 10$\mu\textrm{m}$ thick silicon membrane with oxide-filled trenches in the SOI membrane rim. The micro-heater was fabricated with Pt-RTD(Resistance Thermometer Device)on the same substrate by using MgO as medium layer. The thermal characteristics of the micro-heater with the SOI membrane is 280$^{\circ}C$ at input Power 0.9 W; for the SOI membrane with 10 trenches, it is 580$^{\circ}C$ due to reduction of the external thermal loss. Therefore, the micro-heater with trenches in SOI membrane rim provides a powerful and versatile alternative technology for improving the performance of micro thermal sensors and actuators.

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Thermopile sensor with SOI-based floating membrane and its output circuit

  • 이성준;이윤희;서상희;김태윤;김철주;주병권
    • 센서학회지
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    • 제11권5호
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    • pp.294-300
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    • 2002
  • In this study, we fabricated thermopile infrared sensor with floating membrane structure. Floating membrane was formed by SOI(Silicon On Insulator) structure. In SOI structure, silicon dioxide layer between top silicon layer and bottom silicon substrate was etched by HF solution, then membrane was floated over substrate. After membrane was floated, thermopile pattern was formed on membrane. By insertion of SOI technology, we could obtain thermal isolation structure easily and passivation process for sensor pattern protection was not required during fabrication process. Then, the amplifier circuit for thermopile sensor was fabricated by using $1.5{\mu}m$ CMOS process. The voltage gain of fabricated amplifier was about two hundred.

SOI 멤브레인과 트랜치 구조상에 제작된 발열저항체형 마이크로 유량세선의 특성 (Characteristics of Hot-Film Type Micro-Flowsensors Fabricated on SOI Membrane and Trench Structures)

  • 정귀상;김미목;남태철
    • 한국전기전자재료학회논문지
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    • 제14권8호
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    • pp.658-662
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    • 2001
  • This paper describes on the fabrication and characteristics of hot-film type micro-flowsensors integrated with Pt-RTD(resistance thermometer device) and micro-heater on the SOI(Si-on-insulator) membrane and trench structures, in which MGO thin-film was used as medium layer in order to improve adhesion of Pt thin-film to SiO$_2$ layer. Output voltages increased due to increase of heat-loss from sensor to external. The output voltage was 250 nV at N$_2$ flow rate of 2000 sccm/min, heating power of 0.3 W. The response time($\tau$:63%) was about 42 msec when input flow was step-input. The results indicated that micro-flowsensors with the SOI membrane and trench structures have properties of a high-resolution and ow consume power.

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SOI 웨이퍼를 이용한 압전박막공진기 제작 (Monolithic film Bulk Acoustic Wave Resonator using SOI Wafer)

  • 김인태;김남수;박윤권;이시형;이전국;주병권;이윤희
    • 한국전기전자재료학회논문지
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    • 제15권12호
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    • pp.1039-1044
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    • 2002
  • Film Bulk Acoustic Resonator (FBAR) using thin piezoelectric films can be made as monolithic integrated devices with compatibility to semiconductor process, leading to small size, low cost and high Q RF circuit elements with wide applications in communications area. This paper presents an MMIC compatible suspended FBAR using SOI micromachining. It is possible to make a single crystal silicon membrane using a SOI wafer In fabricating active devices, SOI wafer offers advantage which removes the substrate loss. FBAR was made on the 12㎛ silicon membrane. Electrode and Piezoelectric materials were deposited by RF magnetron sputter. The maximum resonance frequency of FBAR was shown at 2.5GHz range. The reflection loss, K$^2$$\_$eff/, Q$\_$serise/ and Q$\_$parallel/ in that frequency were 1.5dB, 2.29%, 220 and 160, respectively.

The Fabrication of Micro-Heaters with Low-Power Consumption Using SOI and Trench Structures

  • 정귀상;홍석우
    • 한국전기전자재료학회:학술대회논문집
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    • 한국전기전자재료학회 2002년도 춘계합동학술대회 논문집
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    • pp.197-201
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    • 2002
  • This paper presents optimized design, fabrication and thermal characteristics of micro-heaters for thermal MEMS (micro electro mechanical system) applications using SOI and trench structures. The micro-heaters are based on a thermal measurement principle and contains thermal isolation regions of 10 ${\mu}m$-thick Si membranes consisting of oxide-filled trenches in the SOI membrane rim. The micro-heaters were fabricated with Pt-RTD on the same substrate via MgO buff layer between Pt thin-film and $SiO_2$ layer. The thermal characteristics of micro-heater with trench-free SOI membrane structure was $280^{\circ}C$ at input power 0.9 W; in the presence of 10 trenches, it was $580^{\circ}C$ due to reduction of the external thermal loss. Therefore, a micro-heater with trenches in SOI membrane rim structure provides a powerful and versatile alternative technology for enhancing the performance of micro-thermal sensors and actuators.

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SOI 마이크로머시닝 공정을 이용한 Suspended-type 박막공진기의 제작 및 특성평가 (Fabrication and Characterization of Suspended-type Thin Film Resonator Using SOI-Micromachining Process)

  • 주병권;김현호;이시형;이전국;김수원
    • 대한전기학회논문지:전기물성ㆍ응용부문C
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    • 제50권6호
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    • pp.303-306
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    • 2001
  • STFR were fabricated on the floating membrane which was formed by SOI-micromachining process. The floating membranes having a thickness range of $3{\sim}15{\mu}m$ could be simply formed by micromachining the directly-bonded and thinned SOI substrate. The STFR device fabricated on the $15{\mu}m$-thick membrane showed resonance frequency of fr = 1.65 GHz, coupling coefficient of Keff2 = 2.4 %, and series and parallel quality factors of Qs = 91.7 and Qp = 87.7, respectively.

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SOI(Silicon-On-Insulator)- Micromachining 기술을 이용한 MEMS 소자의 제작 (Fabrication of MEMS Devices Using SOI(Silicon-On-Insulator)-Micromachining Technology)

  • 주병권;하주환;서상원;최승우;최우범
    • 한국전기전자재료학회:학술대회논문집
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    • 한국전기전자재료학회 2001년도 하계학술대회 논문집
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    • pp.874-877
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    • 2001
  • SOI(Silicon-On-Insulator) technology is proposed as an alternative to bulk silicon for MEMS(Micro Electro Mechanical System) manufacturing. In this paper, we fabricated the SOI wafer with uniform active layer thickness by silicon direct bonding and mechanical polishing processes. Specially-designed electrostatic bonding system is introduced which is available for vacuum packaging and silicon-glass wafer bonding for SOG(Silicon On Glass) wafer. We demonstrated thermopile sensor and RF resonator using the SOI wafer, which has the merits of simple process and uniform membrane fabrication.

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Modeling and Analysis of a Multi Bossed Beam Membrane Sensor for Environmental Applications

  • Arjunan, Nallathambi;Thangavelu, Shanmuganantham
    • Transactions on Electrical and Electronic Materials
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    • 제18권1호
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    • pp.25-29
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    • 2017
  • This paper presents a unique pressure sensor design for environmental applications. The design uses a new geometry for a multi bossed beam-membrane structure with a SOI (silicon-on-insulator) substrate and a mechanical transducer. The Intellisuite MEMS CAD design tool was used to build and analyze the structure with FEM (finite element modeling). The working principle of the multi bossed beam structure is explained. FEM calculations show that a sensing diaphragm with Mises stress can provide superior linear response compared to a stress-free diaphragm. These simulation results are validated by comparing the estimated deflection response. The results show that, the sensitivity is enhanced by using both the novel geometry and the SOI substrate.

탄소섬유를 이용한 압력센터 제작 및 특성평가 (Fabrication and Characterization of a Pressure Sensor using a Pitch-based Carbon Fiber)

  • 박창신;이동원;강보선
    • 대한기계학회논문집A
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    • 제31권4호
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    • pp.417-424
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    • 2007
  • This paper reports fabrication and characterization of a pressure sensor using a pitch-based carbon fiber. Pitch-based carbon fibers have been shown to exhibit the piezoresistive effect, in which the electric resistance of the carbon fiber changes under mechanical deformation. The main structure of pressure sensors was built by performing backside etching on a SOI wafer and creating a suspended square membrane on the front side. An AC electric field which causes dielectrophoresis was used for the alignment and deposition of a carbon fiber across the microscale gap between two electrodes on the membrane. The fabricated pressure sensors were tested by applying static pressure to the membrane and measuring the resistance change of the carbon fiber. The resistance change of carbon fibers clearly shows linear response to the applied pressure and the calculated sensitivities of pressure sensors are $0.25{\sim}0.35 and 61.8 ${\Omega}/k{\Omega}{\cdot}bar$ for thicker and thinner membrane, respectively. All these observations demonstrated the possibilities of carbon fiber-based pressure sensors.