Molecular-dynamics calculations of energetics and geometries of steps on diamond C(001)

Abstract: The diamond C͑001͒ surface has been observed by scanning tunneling microscopy ͑STM͒ to dimerize similar to Si͑001͒. STM also observed the formation of single-and double-layer steps in this surface. Using an ab initio multicenter molecular-dynamics method, our calculations for the relaxed geometries and the corresponding energetics of these steps show that the detailed structures of these steps are intrinsically different from that of type-A and type-B steps of Si͑001͒ obtained by Chadi. These differences can b… Show more

“…It is clear that similar conditions pertain on vicinal diamond surfaces 13,14 with the crucial difference that on hydrogen plasma-treated diamond (100) surfaces, like those studied here, STM results have revealed the presence of D A steps, and D B steps are absent. 13 The possible equilibrium geometries of diamond (100) surfaces in the presence of single and double steps have been investigated.…”

“…13 The possible equilibrium geometries of diamond (100) surfaces in the presence of single and double steps have been investigated. 14 Interestingly, the equilibrium geometries previously proposed by Chadi for Si(100) 28 may not be the most stable ones on the diamond (100) surface. The driving force for this difference is that diamond is stiffer and more likely to form double bonds than Si.…”

“…6 The realization of the potential of diamond in applications such as optoelectronics and electronic devices 7,8 is dependent not only on controlling the growth of the material but also on understanding its surface electronic structure and in particular the influence of hydrogen. 4 In order to optimize growth processes it is useful to develop techniques for the in situ monitoring of diamond growth and in particular to monitor the behavior of surface steps, [9][10][11][12][13][14] the anisotropic etching of which by atomic hydrogen is known to be important in the production of smooth diamond (100) [C(100)] surfaces. 10 Reflection anisotropy spectroscopy (RAS) 15,16 is a technique that has found application in monitoring the growth of Si, Ge, and III-V compounds [17][18][19][20][21] and the interfaces that are important in the integration of Si, Ge, and GaAs technologies.…”

“…We compare the empirical step spectral signatures with the results of theoretical calculations, within Density Functional Theory (DFT) 36 and the GW 37 method, for the flat and stepped surfaces using the models suggested by Chadi 28 and Tsai and Yeh. 14…”

Contribution of steps to optical properties of vicinal diamond (100):H surfaces

“…It is clear that similar conditions pertain on vicinal diamond surfaces 13,14 with the crucial difference that on hydrogen plasma-treated diamond (100) surfaces, like those studied here, STM results have revealed the presence of D A steps, and D B steps are absent. 13 The possible equilibrium geometries of diamond (100) surfaces in the presence of single and double steps have been investigated.…”

“…13 The possible equilibrium geometries of diamond (100) surfaces in the presence of single and double steps have been investigated. 14 Interestingly, the equilibrium geometries previously proposed by Chadi for Si(100) 28 may not be the most stable ones on the diamond (100) surface. The driving force for this difference is that diamond is stiffer and more likely to form double bonds than Si.…”

“…6 The realization of the potential of diamond in applications such as optoelectronics and electronic devices 7,8 is dependent not only on controlling the growth of the material but also on understanding its surface electronic structure and in particular the influence of hydrogen. 4 In order to optimize growth processes it is useful to develop techniques for the in situ monitoring of diamond growth and in particular to monitor the behavior of surface steps, [9][10][11][12][13][14] the anisotropic etching of which by atomic hydrogen is known to be important in the production of smooth diamond (100) [C(100)] surfaces. 10 Reflection anisotropy spectroscopy (RAS) 15,16 is a technique that has found application in monitoring the growth of Si, Ge, and III-V compounds [17][18][19][20][21] and the interfaces that are important in the integration of Si, Ge, and GaAs technologies.…”

“…We compare the empirical step spectral signatures with the results of theoretical calculations, within Density Functional Theory (DFT) 36 and the GW 37 method, for the flat and stepped surfaces using the models suggested by Chadi 28 and Tsai and Yeh. 14…”

Contribution of steps to optical properties of vicinal diamond (100):H surfaces

“…Just ideal (flat, no defects, no steps) geometries will be here considered. Of course, real surfaces are much more complicated, presenting domains, terraces, and many other unavoidable deviations from the perfect, ideal models we use (see for example [7,8,9,10]). Along with such C surfaces, we will look at the effect of hydrogen coverage on graphene.…”

The fascinating physics of carbon surfaces: first-principles study of hydrogen on C(0 0 1), C(1 1 1) and graphene

Ab Initio Theory of Interband Transitions