Seminar-Peter Wahl
18/05/2011 15:00 (Seminarni mistnost budova A) »more info
Our paper published in PRL May 2011
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Colloquium - R. Moeller
28/04/2011 15:00 (Seminarni mistnost budova A) »more info
Colloquium - A. Heinrich
21/03/2011 15:00 (Seminarni mistnost budova A) »more info
Seminar - Petr Klapetek
14/02/2011 14:00 (Zasedaci mistnost budova B) »more info
Seminar - Guy Le Lay
11/02/2011 11:00 (Seminarni mistnost budova A) »more info
Our paper published in PRL Jan 2011
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Seminar András Berkó
15/11/2010 15:00 (Seminarni mistnost budova A) »more info
Seminar Martin Svec
14/11/2010 15:00 (Seminarni mistnost budova A) »more info
2nd QPlus workshop 8/10/10
2nd International QPlus Workshop 8.10.2010 »more info
Seminar Y. J. Dappe 25/5/10
25/5/2010 10:00 (Seminarni mistnost budova A) »more info
Seminar J. Repp 13/4/2010
14/3/2010 15:00 (Seminarni mistnost budova A) »more info
Seminar T. Novotny 2/3/2010
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Seminar R. Martonak 23/2/10
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4/2/10 Colloquium S. Lindsay
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18/1/10 Our work highlighted on Nanotech.org website.
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30/12/09 Our paper about atomic contrast of KPFM published in PRL
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Seminar J.P. Lewis 9/12/09 14:00
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Seminar P. Kocan 25/11/09 15:00
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14.-15.10. 2009 workshop "Simultaneous STM/AFM measurements using tuning fork based sensors"
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We aim to understand ongoing processes at atomic scale during SPM measurements. The detail knowledge of these processes is necessary for correct interpretation of experimental data and development of new techniques. We apply DFT total energy calculations to simulate complex interaction between SPM tip and sample But addressing these complex problems with a fully converged first-principles description would be still too computationally exigent and in many cases exceeding possibilities of nowadays high performance computers. Therefore we use a home-built fast local orbital DFT code Fireball devised with the aim of computational efficiency. Optionally, calculations are checked with more demand traditional plane-wave DFT methods. In particular, we are interested in these topics:
(i) single-atom chemical identification [1]
(ii) new procedures of atomic manipulations [2,3]
(iii) detail understanding of atomic-scale contrast [4]
(iv) energy dissipation at atomic scale [5].