Deposition/removal of metal atoms on the hex reconstructed (100) surface of Au, Pt and Ir should present intriguing aspects, since a new island implies hex-->square deconstruction of the substrate, and a new crater implies the square-->hex reconstruction of the uncovered layer. To obtain a microscopic understanding of how islands/craters form in these conditions, we have conducted simulations of island and crater growth on Au(100), whose atomistic behavior, including the hex reconstruction on top of the square substrate, is well described by means of classical many-body forces. By increasing/decreasing the Au coverage on Au(100), we find that island/craters will not grow unless they exceed a critical size of about eight to 10 atoms. This value is close to that which explains the non-linear coverage of dependence observed in molecular adsorption on the closely related surface Pt (100). This threshold size is rationalized in terms of a transverse step correlation length, measuring the spatial extent where reconstruction of a given plane is disturbed by the nearby step. (C) 2000 Elsevier Science B.V. All rights reserved.
Islands, craters, and a moving surface step on a hexagonally reconstructed (100) noble metal surface / Passerone, D.; Ercolessi, F.; Tosatti, Erio. - In: SURFACE SCIENCE. - ISSN 0039-6028. - 454:1(2000), pp. 634-641. [10.1016/S0039-6028(00)00205-3]
Islands, craters, and a moving surface step on a hexagonally reconstructed (100) noble metal surface
Tosatti, Erio
2000-01-01
Abstract
Deposition/removal of metal atoms on the hex reconstructed (100) surface of Au, Pt and Ir should present intriguing aspects, since a new island implies hex-->square deconstruction of the substrate, and a new crater implies the square-->hex reconstruction of the uncovered layer. To obtain a microscopic understanding of how islands/craters form in these conditions, we have conducted simulations of island and crater growth on Au(100), whose atomistic behavior, including the hex reconstruction on top of the square substrate, is well described by means of classical many-body forces. By increasing/decreasing the Au coverage on Au(100), we find that island/craters will not grow unless they exceed a critical size of about eight to 10 atoms. This value is close to that which explains the non-linear coverage of dependence observed in molecular adsorption on the closely related surface Pt (100). This threshold size is rationalized in terms of a transverse step correlation length, measuring the spatial extent where reconstruction of a given plane is disturbed by the nearby step. (C) 2000 Elsevier Science B.V. All rights reserved.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.