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8 - Bilayer pseudospin field effect transistor

from Section II - Tunneling devices

Published online by Cambridge University Press:  05 February 2015

By
Dharmendar Reddy ,
Leonard F. Register  and
Sanjay K. Bannerjee
Edited by
Tsu-Jae King Liu  and
Kelin Kuhn
Dharmendar Reddy
Affiliation:
University of Texas at Austin
Leonard F. Register
Affiliation:
University of Texas at Austin
Sanjay K. Bannerjee
Affiliation:
University of Texas at Austin
Tsu-Jae King Liu
Affiliation:
University of California, Berkeley
Kelin Kuhn
Affiliation:
Cornell University, New York
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Summary

Introduction

The bilayer pseudospin field effect transistor (BiSFET) is intended to enable much lower voltage and power operation than possible with complementary metal–oxide–semiconductor (CMOS) field effect transistor (FET)-based logic [1, 2]. The ultimate limits of CMOS are not due to fabrication technology limitations. Rather, they are intrinsic to its operating principles, defined by basic physics such as charge carrier thermionic emission over the channel barrier and quantum mechanical tunneling through it. New operating principles are required. The BiSFET relies on the possibility of room temperature excitonic (electron-hole) superfluid condensation in two dielectrically separated graphene layers [3, 4]. While the physics is interesting in its own right, from the device point of view this many-body physics brings with it the possibility of a strong sensitivity to sub-thermal voltages (sub-kBT/q voltages, where kB is Boltzmann’s constant, T is the temperature in Kelvin, and q is the magnitude of electron charge) in the current–voltage (IV) characteristics [5–7]. With power consumption proportional to the square of voltage, use of voltages on the scale of or less than room temperature kBT/q ≈ 26 mV offers order of magnitude reductions in switching energies as compared to even end-of-the roadmap CMOS [8]. Circuit simulation with 25 mV power supplies show switching energies on the scale of 10 zeptojoules (zJ) per BiSFET (where 1 zJ = 10–21 J = 10–3 aJ)! However, with this potential for voltage reduction also come IV characteristics much different from those of MOSFETs that must be worked around at worst, and may provide new circuit opportunities at best. In terms of interconnects, information would continue to be passed via charge among devices. In this way, BiSFETs would also be compatible with existing electronic devices after voltage level shifts.

Type
Chapter
Information
CMOS and Beyond
Logic Switches for Terascale Integrated Circuits
 , pp. 175 - 206
Publisher: Cambridge University Press
Print publication year: 2015

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References

Banerjee, S. K., Register, L. F., Tutuc, E., Reddy, D., & MacDonald, A. H., “Bilayer pseudospin field-effect transistor (BiSFET): a proposed new logic device.” IEEE Electron Device Letters, 30(2), 158–160 (2009).CrossRefGoogle Scholar
Reddy, D., Register, L. F., Tutuc, E., & Banerjee, S. K., “Bilayer pseudospin field-effect transistor: applications to Boolean logic.” IEEE Transactions on Electron Devices, 57(4), 755–764 (2010).CrossRefGoogle Scholar
Min, H., Bistritzer, R., Su, J.-J., & MacDonald, A. H., “Room-temperature superfluidity in graphene bilayers.” Physics Reviews B, 78(12), 121401 (2008).CrossRefGoogle Scholar
Zhang, C. H. & Joglekar, Y. N., “Excitonic condensation of massless fermions in graphene bilayers.” Physics Reviews B, 77(23), 233405 (2008).CrossRefGoogle Scholar
Basu, D., Register, L., MacDonald, A., & Banerjee, S., “Effect of interlayer bare tunneling on electron-hole coherence in graphene bilayers.” Physics Reviews B, 84(3) (2011).CrossRefGoogle Scholar
Mou, X., Register, L. F., & Banerjee, S. K., “Quantum transport simulation of bilayer pseudospin field-effect transistor (BiSFET) on tightbinding Hartree-Fock model.” In Simulation of Semiconductor Processes and Devices, 2013 International Conference on (2013).
Mou, X., Register, L. F., & Banerjee, S. K., “Quantum transport simulations on the feasibility of the bilayer pseudospin field effect transistor (BiSFET).” In Electron Device Meeting (IEDM), 2013 International, Technical Digest, pp. 4.7.1–4.7.4 (2013).
International Technology Roadmap for Semiconductors. Available online at .
Mendez, E. E., Esaki, L., & Chang, L. L., “Quantum Hall effect in a two-dimensional electron-hole gas.” Physics Review Letters, 55(20), 2216 (1985).CrossRefGoogle Scholar
Spielman, I. B., Eisenstein, J. P., Pfeiffer, L. N., & West, K. W., “Resonantly enhanced tunneling in a double layer quantum Hall ferromagnet.” Physics Review Letters, 84(25), 5808 (2000).CrossRefGoogle Scholar
Pohlt, M., Lynass, M., Lok, J. G. S. et al., “Closely spaced and separately contacted two-dimensional electron and hole gases by in situ focused-ion implantation.” Applied Physics Letters, 80(12), 2105–2107 (2002).CrossRefGoogle Scholar
Seamons, J. A., Tibbetts, D. R., Reno, J. L., & Lilly, M. P., “Undoped electron-hole bilayers in a GaAs/AlGaAs double quantum well.” Applied Physics Letters, 90(5), 052103–3 (2007).CrossRefGoogle Scholar
Tiemann, L. et al., “Critical tunneling currents in the regime of bilayer excitons.” New Journal of Physics, 10(4), 045018 (2008).CrossRefGoogle Scholar
Nandi, D., Finck, A. D. K., Eisenstein, J. P., Pfeiffer, L. N., & West, K. W., “Exciton condensation and perfect Coulomb drag.” Nature, 488(7412), 481–484 (2012).CrossRefGoogle ScholarPubMed
Sodemann, I., Pesin, D., & MacDonald, A., “Interaction-enhanced coherence between two-dimensional Dirac layers.” Physics Reviews B, 85(19) (2012).CrossRefGoogle Scholar
Su, J.-J. & MacDonald, A. H., “How to make a bilayer exciton condensate flow.” Nature Physics, 4(10), 799–802 (2008).CrossRefGoogle Scholar
Ng, K. K., Complete Guide to Semiconductor Devices (New York: Wiley, 2002), pp. 569–574.Google Scholar
Mazumder, P., Kulkarni, S., Bhattacharya, M., Ping, S. Jian, and Haddad, G. I., “Digital circuit applications of resonant tunneling devices.” Proceedings of the IEEE, 86(4), 664–686 (1998).CrossRefGoogle Scholar
Wu, K., Sachid, A., Yang, F.-L., & Hu, C., “Toward 44% switching energy reduction for FinFETs with vacuum gate spacer.” In Simulation of Semiconductor Processes and Devices, 2012 International Conference on, pp. 253–256 (2012).
Weitz, R. T., Allen, M. T., Feldman, B. E., Martin, J., & Yacoby, A., “Broken-symmetry states in doubly gated suspended bilayer graphene.” Science, 330(6005), 812–816 (2010).CrossRefGoogle ScholarPubMed
Lozovik, Y. E. & Yudson, V. I., “Feasibility of superfluidity of paired spatially separated electrons and holes; a new superconductivity mechanism.” Soviet Journal of Experimental and Theoretical Physics Letters, 22, 274–275 (1975).Google Scholar
Basu, D., Register, L., Reddy, D., MacDonald, A., & Banerjee, S., “Tight-binding study of electron-hole pair condensation in graphene bilayers: Gate control and system-parameter dependence.” Physics Reviews B, 82(7), (2010).CrossRefGoogle Scholar
Avouris, P., Chen, Z., & Perebeinos, V., “Carbon-based electronics.” Nature Nanotechnology, 2(10), 605–615 (2007).CrossRefGoogle ScholarPubMed
Lozovik, Y. E. & Sokolik, A. A., “Electron-hole pair condensation in a graphene bilayer.” JETP Letters, 87(1), 55–59 (2011).CrossRefGoogle Scholar
Jadaun, P., Movva, H. C. P., Register, L. F., & Banerjee, S. K., “Theory and synthesis of bilayer graphene intercalated with ICl and IBr for low power device applications.” Journal of Applied Physics, 114(6), 063702 (2013).CrossRefGoogle Scholar
Register, L. F., Mau, X., Reddy, D. et al., “Bilayer pseudo-spin field effect transistor (BiSFET): concepts and critical issues for realization.” Invited presentation at the 221st Electrochemical Society Meeting, Seattle, Washington, May 7, 2012.

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