Quenching surface states with the tip: STM scans on Fe(100)

W.A. Hofer¹, J. Redinger², A. Biedermann³ and P. Varga³

¹Department of Physics and Astronomy, University College London, Gower Street, London WC1E 6BT, United Kingdom
²Center for Computational Materials Science, Getreidemarkt 9/158, Technische Universität Wien, A-1060 Wien, Austria
³Institut für Allgemeine Physik, Technische Universität Wien, A-1040 Wien, Austria

Surf. Sci. 482-485 (2001) 1113-1118

STM topographies and spectroscopies are compared with first principles simulations using the transfer-Hamiltonian method. We show that simulations agree with measurements in the range above 400 pm tip-sample separation, provided the tungsten tip is terminated by a (100) or (111) face. Measurements disagree with experiments for the (110) face. The approach fails to describe tunneling topographies in the range below 400 pm. It is argued that this failure is due to interactions, and it is demonstrated how quenching of surface states by the approaching tip accounts for the experimental features in this range.

Corresponding author: W.A. Hofer. Reprints also available from P. Varga (varga).

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Quenching surface states with the tip: STM scans on Fe(100)

W.A. Hofer1, J. Redinger2, A. Biedermann3 and P. Varga3

Surf. Sci. 482-485 (2001) 1113-1118

W.A. Hofer¹, J. Redinger², A. Biedermann³ and P. Varga³