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Author Patel, Pratik Ashvin
Title Steep Turn On/Off "Green" Tunnel Transistors
book jacket
Descript 104 p
Note Source: Dissertation Abstracts International, Volume: 72-05, Section: B, page: 2994
Adviser: Chenming Hu
Thesis (Ph.D.)--University of California, Berkeley, 2010
Scaling of supply voltage Vdd has significantly slowed down since the 130 nm node. As a result, integrated circuit (IC) power consumption has been on the rapid rise. This presents a serious thermal management challenge and potential limiter of integration density as well as a rapidly growing portion of the world electricity demand. The problem lies in the 60 mV/dec swing limitation of any device involving charge flow over energy barrier (i.e., current state of art CMOS). This requires at least 60 mV to decrease the transistor current by 10X. The future low power or "green" energy efficient scenario would benefit from a device that is friendlier to Vdd scaling. A transistor where carriers tunnel through rather than flow over a barrier is not subject to this limitation. However, achieving sub 60 mV/dec at current ranges of interest and over many decades is not trivial when relying solely on transmission probability modulation (i.e., increase/decrease of tunnel barrier width). Instead, if the absence/presence of tunneling state overlap is exploited a sharp "off" to "on" transition is achievable. By engineering the transistor device structure such that this overlap (i.e., onset of tunneling) occurs in a region of high electric field results in steep sub 60 mV/dec response over many decades of current. One novel design utilizes heavily doped, ultra shallow N+/P+ junctions to achieve this "sudden tunneling overlap" effect. Another design involves use of ultra thin body silicon-on-insulator (5 nm) to achieve a similar effect. Simulation results show sub 500 mV Vdd is possible if suitable low-E g material is introduced. Both designs have been fabricated in silicon and their measurement results are presented
School code: 0028
Host Item Dissertation Abstracts International 72-05B
Subject Engineering, Electronics and Electrical
Alt Author University of California, Berkeley. Electrical Engineering & Computer Sciences
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