• Electronics and Telecommunications Trends
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• v.38 no.6
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• pp.52-61
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• 2023

With semiconductor scaling approaching the physical limits, devices including CMOS (complementary metal-oxide-semiconductor) components have managed to overcome yet are currently struggling with several technical issues like short-channel effects. Evolving from the process node of 22 nm with FinFET (fin field effect transistor), state-of-the-art semiconductor technology has reached the 3 nm node with the GAA-FET (gate-all-around FET), which appropriately addresses the main issues of power, performance, and cost. Technical problems remain regarding the foundry of GAA-FET, and next-generation devices called post-GAA transistors have not yet been devised, except for the CFET (complementary FET). We introduce a CFET that spatially stacks p- and n-channel FETs on the same footprint and describe its structure and fabrication. Technical details like stacking of nanosheets, special spacers, hetero-epitaxy, and selective recess are more thoroughly reviewed than in similar articles on CFET fabrication.

• 한국정보디스플레이학회:학술대회논문집
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• 2008.10a
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• pp.841-843
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• 2008

We elucidated a way to increase the mobility of $\pi$-stacked materials by comparing various single-crystal OFETs. A high field-effect mobility (of $3.7\;cm^2/Vs$) was obtained by increasing the effective $\pi$-stacking area and decreasing the $\pi$-stacking distance.

• Journal of the Korean Crystal Growth and Crystal Technology
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• v.11 no.5
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• pp.207-210
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• 2001

Metal-organic VPE (MOVPE) epitaxial growth procedure and related device fabrication technique are reported for GaInP-based epitaxial materials and devices. For GaInP/GaInAs two-dimensional electron-gas field-effect transistor (TEGFET), a promising epitaxial stacking structure resulting in enhanced electron mobility is given. In conjunction with this, a new device fabrication technique to improve luminous intensity of GaInP-based LED is also shown.

• Journal of the Institute of Electronics and Information Engineers
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• v.52 no.5
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• pp.58-65
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• 2015

This paper presents the design of an implantable stimulation IC intended for neural prosthetic devices using $0.18-{\mu}m$ standard CMOS technology. The proposed single-channel biphasic current stimulator prototype is designed to deliver up to 1 mA of current to the tissue-equivalent $10-k{\Omega}$ load using 12.8-V supply voltage. To utilize only low-voltage standard CMOS transistors in the design, transistor stacking with dynamic gate biasing technique is used for reliable operation at high-voltage. In addition, active charge balancing circuit is used to maintain zero net charge at the stimulation site over the complete stimulation cycle. The area of the total stimulator IC consisting of DAC, current stimulation output driver, level-shifters, digital logic, and active charge balancer is $0.13mm^2$ and is suitable to be applied for multi-channel neural prosthetic devices.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.26 no.5
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• pp.682-687
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• 2022

In this paper, the research results on monolithic three-dimensional integrated-circuit (M3DICs) stacked with tunneling field effect transistors (TFETs) are introduced. Unlike metal-oxide-semiconductor field-effect transistors (MOSFETs), TFETs are designed differently from the layout of symmetrical MOSFETs because the source and drain of TFET are asymmetrical. Various monolithic 3D inverter (M3D-INV) structures and layouts are possible due to the asymmetric structure, and among them, a simple inverter structure with the minimum metal layer is proposed. Using the proposed M3D-INV, this M3D logic gates such as NAND and NOR gates by sequentially stacking TFETs are proposed, respectively. The simulation results of voltage transfer characteristics of the proposed M3D logic gates are investigated using mixed-mode simulator of technology computer aided design (TCAD), and the operation of each logic circuit is verified. The cell area for each M3D logic gate is reduced by about 50% compared to one for the two-dimensional planar logic gates.

• ETRI Journal
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• v.44 no.3
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• pp.491-503
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• 2022

Metal-oxide-semiconductor field-effect transistors (MOSFETs) are continuously scaling down in the nanoscale region to improve the functionality of integrated circuits. The scaling down of MOSFET devices causes short-channel effects in the nanoscale region. In nanoscale region, leakage current components are increasing, resulting in substantial power dissipation. Very large-scale integration designers are constantly exploring different effective methods of mitigating the power dissipation. In this study, a transistor-level input-controlled stacking (ICS) approach is proposed for minimizing significant power dissipation. A low-power ICS approach is extensively discussed to verify its importance in low-power applications. Circuit reliability is monitored for process and voltage and temperature variations. The ICS approach is designed and simulated using Cadence's tools and compared with existing low-power and high-speed techniques at a 22-nm technology node. The ICS approach decreases power dissipation by 84.95% at a cost of 5.89 times increase in propagation delay, and improves energy dissipation reliability by 82.54% compared with conventional circuit for a ring oscillator comprising 5-inverters.

• Proceedings of the Korean Vacuum Society Conference
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• 2011.02a
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• pp.482-483
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• 2011

Graphene is a good candidate for the future nano-electronic materials because it has excellent conductivity, mobility, transparency, flexibility and others. Until now, most graphene researches are focused on the nano electronic device applications, however, biological application of graphene has been relatively less reported. We have fabricated a deoxyribonucleic acid (DNA) conjugated graphene field-effect transistor (FET) and measured the electrical transport characteristics. We have used graphene sheets grown on Ni substrates by chemical vapour deposition. The Raman spectra of graphene sheets indicate high quality and only a few number of layers. The synthesized graphene is transferred on top of the substrate with pre-patterned electrodes by the floating-and-scooping method [1]. Then we applied adhesive tapes on the surface of the graphene to define graphene flakes of a few micron sizes near the electrodes. The current-voltage characteristic of the graphene layer before stripping shows linear zero gate bias conductance and no gate operation. After stripping, the zero gate bias conductance of the device is reduced and clear gate operation is observed. The change of FET characteristics before and after stripping is due to the formation of a micron size graphene flake. After combined with 30 base pairs single-stranded poly(dT) DNA molecules, the conductance and gate operation of the graphene flake FETs become slightly smaller than that of the pristine ones. It is considered that DNA is to be stably binding to the graphene layer due to the ${\pi}-{\pi}$ stacking interaction between nucleic bases and the surface of graphene. And this binding can modulate the electrical transport properties of graphene FETs. We also calculate the field-effect mobility of pristine and DNA conjugated graphene FET devices.

• Journal of the Microelectronics and Packaging Society
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• v.19 no.4
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• pp.71-78
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• 2012

This paper describes trends in conventional scaling compared with advanced technologies such as 3D integration (3DI) and bumpless through-silicon via (TSV) processes, as well as the characteristics of CMOS (Complementary Metal Oxide Semiconductor) Logic device after thinning the wafers to less than $10{\mu}m$. Each module process including thinning, stacking, and TSV, is optimized for 3D Wafer-on-Wafer (WOW) application. Optimization results are discussed with valuable data in detail. Since vertical wiring of bumpless TSV can be connected directly to the upper and lower substrates by self-alignment, bumps are not necessary when TSV interconnects are used.

• Proceedings of the Korean Institute of Surface Engineering Conference
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• 2018.06a
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• pp.46-46
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• 2018

메모리 소자의 수요가 데스크톱 컴퓨터의 정체와 모바일 기기의 폭발적인 증가로 NAND flash 메모리의 고집적화로 이어져서 3차원 집적 기술의 고도화가 중요한 요소가 되고 있다. 1 mm 정도의 얇은 웨이퍼 상에 만들어지는 메모리 소자는 실제 두께는 몇 마이크로미터 되지 않는다. 수직방향으로 여러 장의 웨이퍼를 연결하면 폭 방향으로 이미 거의 한계에 도달해있는 크기 축소(shrinking) 기술에 의지 하지 않고서도 메모리 소자의 용량을 증대 시킬 수 있다. CPU, AP등의 논리 연산 소자의 경우에는 발열 문제로 3D stacking 기술의 구현이 쉽지 않지만 메모리 소자의 경우에는 저 전력화를 통해서 실용화가 시작되었다. 스마트폰, 휴대용 보조 저장 매체(USB memory, SSD)등에 수 십 GB의 용량이 보편적인 현재, FEOL, BEOL 기술을 모두 가지고 있는 국내의 반도체 소자 업체들은 자연스럽게 TSV 기술과 이에 필요한 장비의 개발에 관심을 가지게 되었다. 특히 이 중 TSV용 스퍼터링 장치는 transistor의 main contact 공정에 전 세계 시장의 90% 이상을 점유하고 있는 글로벌 업체의 경우에도 완전히 만족스러운 장비를 공급하지는 못하고 있는 상태여서 연구 개발의 적절한 시기이다. 기본 개념은 일반적인 마그네트론 스퍼터링이 중성 입자를 타겟 표면에서 발생시키는데 이를 다시 추가적인 전력 공급으로 전자 - 중성 충돌로 인한 이온화 과정을 추가하고 여기서 발생된 타겟 이온들을 웨이퍼의 표면에 최대한 수직 방향으로 입사시키려는 노력이 핵심이다. 본 발표에서는 고전력 이온화 스퍼터링 시스템의 자기장 해석, 냉각 효율 해석, 멀티 모듈 회전 자석 음극에 대한 동역학적 분석 결과를 발표한다. 그림1에는 이중 회전 모듈에 대한 다물체 동역학 해석을 Adams s/w package로 해석하기 위하여 작성한 모델이고 그림2는 180도 회전한 서브 모듈의 위상이 음극 냉각에 미치는 효과를 CFD-ACE+로 유동 해석한 결과를 나타내고 있다.

• Journal of Information Display
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• v.12 no.1
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• pp.5-10
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• 2011

A novel architecture and proprietary electronic inks were developed to provide disruptive digital-media solutions based on an electrokinetic technology platform. The flexible reflective electronic media (eMedia) was fabricated by imprinting three-dimensional microscale structures with a roll-to-roll manufacturing platform. The HP technologies enable the required attributes for eMedia, such as low power, transparency, print-quality color, continuous levels of gray, and lowcost scalability. Pixelation was also demonstrated by integrating with the prototype oxide thin-film transistor backplane, and the system architecture was further developed by stacking primary-colorant layers for color reflective-display application. The innovations described in this paper are currently being developed further for the eSkins, eSignage, and ePaper applications.