Carrier tunneling, current instabilities, and negative differential conductivity in nanocrystalline silicon - Silicon dioxide superlattices

B. V. Kamenev; G. F. Grom; D. J. Lockwood; J. P. McCaffrey; B. Laikhtman; L. Tsybeskov

Carrier tunneling, current instabilities, and negative differential conductivity in nanocrystalline silicon - Silicon dioxide superlattices

B. V. Kamenev^*, G. F. Grom, D. J. Lockwood, J. P. McCaffrey, B. Laikhtman, L. Tsybeskov

^*Corresponding author for this work

Racah Institute of Physics

Research output: Contribution to journal › Conference article › peer-review

Abstract

Low temperature measurements of differential conductivity in nanocrystalline Si - amorphous SiO₂ superlattices surprisingly reveal a clear double-peak structure associated with tunneling via levels of light and heavy holes. Numerical simulations show not only detailed agreement with the experiment but also predict that the studied system has no stable solutions for carrier concentration higher than 10¹⁷ cm^-3. According to this prediction, partial screening of the external electric field generates current instabilities and oscillations, and that is experimentally observed. The developed model also suggests that a more uniform electric field and stabilization of carrier transport at a higher level of carrier density can be achieved under transient carrier injection.

Original language	English
Pages (from-to)	813-818
Number of pages	6
Journal	Materials Research Society Symposium - Proceedings
Volume	737
State	Published - 2003
Event	Quantum Confined Semiconductor Nanostructures - Boston MA, United States Duration: 2 Dec 2002 → 5 Dec 2002

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title = "Carrier tunneling, current instabilities, and negative differential conductivity in nanocrystalline silicon - Silicon dioxide superlattices",

abstract = "Low temperature measurements of differential conductivity in nanocrystalline Si - amorphous SiO2 superlattices surprisingly reveal a clear double-peak structure associated with tunneling via levels of light and heavy holes. Numerical simulations show not only detailed agreement with the experiment but also predict that the studied system has no stable solutions for carrier concentration higher than 1017 cm-3. According to this prediction, partial screening of the external electric field generates current instabilities and oscillations, and that is experimentally observed. The developed model also suggests that a more uniform electric field and stabilization of carrier transport at a higher level of carrier density can be achieved under transient carrier injection.",

author = "Kamenev, {B. V.} and Grom, {G. F.} and Lockwood, {D. J.} and McCaffrey, {J. P.} and B. Laikhtman and L. Tsybeskov",

year = "2003",

language = "אנגלית",

volume = "737",

pages = "813--818",

journal = "Materials Research Society Symposium - Proceedings",

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note = "Quantum Confined Semiconductor Nanostructures ; Conference date: 02-12-2002 Through 05-12-2002",

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T1 - Carrier tunneling, current instabilities, and negative differential conductivity in nanocrystalline silicon - Silicon dioxide superlattices

AU - Kamenev, B. V.

AU - Grom, G. F.

AU - Lockwood, D. J.

AU - McCaffrey, J. P.

AU - Laikhtman, B.

AU - Tsybeskov, L.

PY - 2003

Y1 - 2003

N2 - Low temperature measurements of differential conductivity in nanocrystalline Si - amorphous SiO2 superlattices surprisingly reveal a clear double-peak structure associated with tunneling via levels of light and heavy holes. Numerical simulations show not only detailed agreement with the experiment but also predict that the studied system has no stable solutions for carrier concentration higher than 1017 cm-3. According to this prediction, partial screening of the external electric field generates current instabilities and oscillations, and that is experimentally observed. The developed model also suggests that a more uniform electric field and stabilization of carrier transport at a higher level of carrier density can be achieved under transient carrier injection.

AB - Low temperature measurements of differential conductivity in nanocrystalline Si - amorphous SiO2 superlattices surprisingly reveal a clear double-peak structure associated with tunneling via levels of light and heavy holes. Numerical simulations show not only detailed agreement with the experiment but also predict that the studied system has no stable solutions for carrier concentration higher than 1017 cm-3. According to this prediction, partial screening of the external electric field generates current instabilities and oscillations, and that is experimentally observed. The developed model also suggests that a more uniform electric field and stabilization of carrier transport at a higher level of carrier density can be achieved under transient carrier injection.

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SN - 0272-9172

VL - 737

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EP - 818

JO - Materials Research Society Symposium - Proceedings

JF - Materials Research Society Symposium - Proceedings

T2 - Quantum Confined Semiconductor Nanostructures

Y2 - 2 December 2002 through 5 December 2002

ER -

Carrier tunneling, current instabilities, and negative differential conductivity in nanocrystalline silicon - Silicon dioxide superlattices

Abstract

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