TY - JOUR
T1 - Temperature dependence in nanoindentation of a metal substrate by a diamondlike tip
AU - Hsieh, Jin Yuan
AU - Ju, Shin Pon
AU - Li, Shyh Hong
AU - Hwang, Chi Chuan
N1 - Funding Information:
The authors gratefully acknowledge the financial support to this research by the National Science Council, Taiwan, under Grant Nos. NSC 92/2511-S-006-010, NSC 92-2212-E-006-066, and NSC 92-2212-E-159-001.
PY - 2004/11
Y1 - 2004/11
N2 - In this investigation, we simulated the nanoindentation of a copper substrate by a diamondlike tip, using molecular dynamics method. A series of simulations according to distinct system temperatures were performed to analyze the temperature dependences of some important physical quantities occurring in the indentation. We found that the maximal normal forces on the tip atoms, both the repulsive and the attractive, the elastic modulus of the indentation system and the network done by the tip during the indentation cycle all decrease with increasing system temperature. By these dependences, we then identified the critical temperature for the transition of plastic flow mechanism in the substrate. The evolution of the crystalline structure in the substrate was analyzed by examining the variation of the structure factor, which measures the perfection of the crystalline structure, during the indentation cycle. An important physical quantity is the difference between the equilibrium absolute values of structure factor before and after the indentation, which can be used to measure the permanent deformation in the substrate produced by the indentation. We found that the difference increases with increasing temperature if the system temperature is below the critical temperature.
AB - In this investigation, we simulated the nanoindentation of a copper substrate by a diamondlike tip, using molecular dynamics method. A series of simulations according to distinct system temperatures were performed to analyze the temperature dependences of some important physical quantities occurring in the indentation. We found that the maximal normal forces on the tip atoms, both the repulsive and the attractive, the elastic modulus of the indentation system and the network done by the tip during the indentation cycle all decrease with increasing system temperature. By these dependences, we then identified the critical temperature for the transition of plastic flow mechanism in the substrate. The evolution of the crystalline structure in the substrate was analyzed by examining the variation of the structure factor, which measures the perfection of the crystalline structure, during the indentation cycle. An important physical quantity is the difference between the equilibrium absolute values of structure factor before and after the indentation, which can be used to measure the permanent deformation in the substrate produced by the indentation. We found that the difference increases with increasing temperature if the system temperature is below the critical temperature.
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U2 - 10.1103/PhysRevB.70.195424
DO - 10.1103/PhysRevB.70.195424
M3 - Article
AN - SCOPUS:12344317978
SN - 0163-1829
VL - 70
SP - 1
EP - 9
JO - Physical Review B - Condensed Matter and Materials Physics
JF - Physical Review B - Condensed Matter and Materials Physics
IS - 19
M1 - 195424
ER -