Atomic-scale friction on diamond: a comparison of different sliding directions on (001) and (111) surfaces using MD and AFM.

@article{Gao2007AtomicscaleFO,
  title={Atomic-scale friction on diamond: a comparison of different sliding directions on (001) and (111) surfaces using MD and AFM.},
  author={Guangtu Gao and Rachel J. Cannara and Robert W. Carpick and Judith A. Harrison},
  journal={Langmuir : the ACS journal of surfaces and colloids},
  year={2007},
  volume={23 10},
  pages={
          5394-405
        }
}
Atomic force microscopy (AFM) experiments and molecular dynamics (MD) simulations were conducted to examine single-asperity friction as a function of load, surface orientation, and sliding direction on individual crystalline grains of diamond in the wearless regime. Experimental and simulation conditions were designed to correspond as closely as state-of-the-art techniques allow. Both hydrogen-terminated diamond (111)(1 x 1)-H and the dimer row-reconstructed diamond (001)(2 x 1)-H surfaces were… 
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References

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Diamond, diamond-like carbon (DLC), and other related materials (i.e., carbon nitride and cubic boron nitride [CBN]) are some of the hardest materials known and offer several other outstanding