This research explores InP-based tunnel diodes to supplement existing memory and high speed IC technology. Tunneling-based static random access memory (TSRAM) uses the bistability of tunnel diodes to construct memory elements and requires tunnel diodes with peak currents exceeding transistor leakage currents, high peak-to-valley ratio (PVR) and low valley currents and voltages. InAlAs-InGaAs resonant interband tunnel diodes (RITD) were investigated for TSRAM through design, fabrication and electrical characterizations. In particular, the effects of doping density, barrier thicknesses and alloy composition on the RITD properties were studied. Tunnel diodes with peak and valley currents spanning 5 orders of magnitude, with PVRs as high as 70 were demonstrated through 3x variation in the effective doping density. Valley currents as low as 0.07 nA/mum2, which is the lowest reported for TSRAM tunnel diodes, and valley voltages as low as 250 mV were demonstrated. Submicron device scaling was explored through the development of a fabrication process.;To reduce the parasitics in tunnel diode/transistor integrated circuits, a novel self-aligned contact process using dielectric spacers and benzocyclobutene etchback was developed. Silicon nitride and oxide spacer sidewalls were demonstrated through the development of anisotropic plasma etches. InP-based monolithically integrated resonant tunnel diodes and heterojunction bipolar transistors were fabricated using this process and electrically characterized.
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机译:这项研究探索了基于InP的隧道二极管,以补充现有的存储器和高速IC技术。基于隧道的静态随机存取存储器(TSRAM)使用隧道二极管的双稳性来构造存储元件,并且需要峰值电流超过晶体管泄漏电流,高峰谷比(PVR)以及低谷值电流和电压的隧道二极管。通过设计,制造和电气特性研究了用于TSRAM的InAlAs-InGaAs谐振带间隧道二极管(RITD)。特别地,研究了掺杂密度,势垒厚度和合金组成对RITD性能的影响。通过有效掺杂密度的3倍变化,证明了峰值和谷值电流跨越5个数量级,PVR高达70的隧道二极管。谷值电流低至0.07 nA / m2,这是TSRAM隧道二极管所报告的最低值,并且谷值电压低至250 mV。通过制造工艺的发展,探索了亚微米器件的规模。为了减少隧道二极管/晶体管集成电路中的寄生效应,开发了一种使用介电垫片和苯并环丁烯回蚀的新型自对准接触工艺。通过各向异性等离子体刻蚀的发展证明了氮化硅和氧化物隔离物的侧壁。使用该工艺制造了基于InP的单片集成谐振隧道二极管和异质结双极晶体管,并对其进行了电气特性分析。
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