Si(001) step dynamics

Chris Pearson; Brian Borovsky; Michael Krueger; Robert Curtis; Eric Ganz

doi:10.1103/PhysRevLett.74.2710

Si(001) step dynamics

Chris Pearson, Brian Borovsky, Michael Krueger, Robert Curtis, Eric Ganz

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Abstract

We used a scanning tunneling microscope to study the dynamics of step edges on the Si(001)- 2×1 reconstructed surface at temperatures from 520 to 700 K. We count changes in step edge position to determine the rates of attachment and detachment events which occur in units of four Si atoms (two dimers). Surface mass transport at these temperatures is dominated by kink diffusion. From an Arrhenius plot we find the effective activation energy for kink diffusion to be 0.97±0.12 eV with a prefactor of 3×105 s-1.

Original language	English (US)
Pages (from-to)	2710-2713
Number of pages	4
Journal	Physical review letters
Volume	74
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevLett.74.2710
State	Published - 1995
Externally published	Yes

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title = "Si(001) step dynamics",

abstract = "We used a scanning tunneling microscope to study the dynamics of step edges on the Si(001)- 2×1 reconstructed surface at temperatures from 520 to 700 K. We count changes in step edge position to determine the rates of attachment and detachment events which occur in units of four Si atoms (two dimers). Surface mass transport at these temperatures is dominated by kink diffusion. From an Arrhenius plot we find the effective activation energy for kink diffusion to be 0.97±0.12 eV with a prefactor of 3×105 s-1.",

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T1 - Si(001) step dynamics

AU - Pearson, Chris

AU - Borovsky, Brian

AU - Krueger, Michael

AU - Curtis, Robert

AU - Ganz, Eric

PY - 1995

Y1 - 1995

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AB - We used a scanning tunneling microscope to study the dynamics of step edges on the Si(001)- 2×1 reconstructed surface at temperatures from 520 to 700 K. We count changes in step edge position to determine the rates of attachment and detachment events which occur in units of four Si atoms (two dimers). Surface mass transport at these temperatures is dominated by kink diffusion. From an Arrhenius plot we find the effective activation energy for kink diffusion to be 0.97±0.12 eV with a prefactor of 3×105 s-1.

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JO - Physical review letters

JF - Physical review letters

IS - 14

ER -

Si(001) step dynamics

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