Indentation in single-crystal 6H silicon carbide: Experimental investigations and finite element analysis

Pang, Xavier; Tymicki, E.; Roy, Anish

doi:10.1016/j.ijmecsci.2017.11.021

Cited by 22 publications

(4 citation statements)

References 29 publications

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“…Most of these studies were aimed at understanding the global response of the material in which various mechanisms are active apart from defect evolution in single crystals such as grain boundary effects. Experimental nano-indentation studies have been used to measure the hardness of the material [17][18][19][20][21][22] and determine the elastic constant; but it should be noted that due to complex state of stress within the material (a combination of hydrostatic compression as well as that of shear depending upon the type of the indenter and distance of the indenter from the point being measured) in nano-indentation tests these cannot be effectively used for stress-strain determination and/or study of defect evolution within the material under a specific type of loading situation. Numerical studies of nanoindentation on the material has also been carried out [19,23] with an objective to explain the governing deformation mechanisms.…”

Section: Introductionmentioning

confidence: 99%

“…Experimental nano-indentation studies have been used to measure the hardness of the material [17][18][19][20][21][22] and determine the elastic constant; but it should be noted that due to complex state of stress within the material (a combination of hydrostatic compression as well as that of shear depending upon the type of the indenter and distance of the indenter from the point being measured) in nano-indentation tests these cannot be effectively used for stress-strain determination and/or study of defect evolution within the material under a specific type of loading situation. Numerical studies of nanoindentation on the material has also been carried out [19,23] with an objective to explain the governing deformation mechanisms. There exists other molecular dynamics (MD) simulation of 6H SiC (and/or other polytypes) under various types of complex loading conditions such as nano-cutting [24], nano scratching [23], sliding friction [25], ductile-regime machining [26][27][28] nuclear irradiation [29][30][31] and also shock studies [32][33][34]; however, almost all of these studies (including those in the referred literature of the above mentioned references) were primarily aimed at validating respective experimental results in a global sense rather than providing a detailed local mechanistic study into the cause of microstructural deformation induced in the sample under the applied loading conditions.…”

Section: Introductionmentioning

confidence: 99%

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Physics of molecular deformation mechanism in 6H-SiC

Mitra

Ramesh

2023

Modelling Simul. Mater. Sci. Eng.

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Even though there have been several studies in literature of 6H SiC, aproper physics based understanding of the molecular deformation mechanisms of thematerial under different loading conditions is still lacking. Experimentally, the brittlenature of the material leads to difficulties associated with in-situ determination ofmolecular deformation mechanisms of the material under an applied load; whereas,the complex material structure along with the bonding environment prevents propercomputational identification of different types of inelasticity mechanisms within thematerial. Molecular dynamics study (on successful verification of the interatomicpotential with experimental results) of pristine single crystals of 6H SiC have beenused to probe the physics of molecular deformation mechanisms of the material alongwith its inherent orientational anisotropy. The study elucidates the experimentallyobserved mechanisms of defect nucleation and evolution through a detailed analysis ofradial distribution functions, x-ray diffraction as well as phonon vibrational studies ofthe single crystal. Studies have been presented at room temperature, initial hightemperature and different types of confinement effects of the material (includinghydrostatic and different biaxial loading cases). The confinement resulted in anincrease in stress and stiffness whereas increase in initial temperature resulted in adecrease compared to uniaxial stress loading conditions at room temperature.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Physics of molecular deformation mechanism in 6H-SiC

Mitra

Ramesh

2023

Modelling Simul. Mater. Sci. Eng.

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“…Datye et al [23] evaluated the fracture toughness and plastic behavior of 6H-SiC single crystal by nanoindentation. Pang et al [24] conducted indentation experiments on 6H-SiC single crystal, and the results showed that classical crystal plasticity theory can be reliably applied in predicting the plastic deformation of ceramic at small scales. Goal et al [25] analyzed displacement controlled quasistatic nanoindentations on single crystal 4H-SiC, and an analytical stress analysis was carried out to calculate the theoretical shear strength and tensile stress.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Behavior Investigation of 4H-SiC Single Crystal at the Micro–Nano Scale

Chai

et al. 2020

Micromachines

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In this paper, theoretical models of the critical indentation depth and critical force on brittle materials using cleavage strength and contact theory are proposed. A Berkovich indenter is adopted for nanoindentation tests on a 4H-SiC single crystal sample to evaluate its mechanical behaviors. The stages of brittle material deformation (elastic, plastic, and brittle) can be characterized by the load versus indentation depth curves through the nanoindentation test. The curve of the elastic deformation stage follows the Hertz contact theory, and plastic deformation occurs at an indentation depth of up to 10 nm. The mechanism of 4H-SiC single crystal cracking is discussed, and the critical indentation depth and critical force for the plastic-brittle transition are obtained through the occurrence of the pop-in point. This shows that the theoretical results have good coherence with the test results. Both the values of the elastic modulus and hardness decrease as the crack length increases. In order to obtain more accurate mechanical property values in the nanoindentation test for brittle materials such as SiC, GaN, and sapphire, an appropriate load that avoids surface cracks should be adopted.

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“…Nawaz et al investigated the nanoscale elastic-plastic deformation behavior of single crystal 6H-SiC systematically by using nanoindentation with a Berkovich indenter and observed the effect of loading rates on the critical pop-in load, pop-in displacement and maximum shear stress [16]. Pang et al presented an experimental and numerical analysis of the deformation behavior of single-crystal 6H-SiC in nanoindentation, the results showed that classical crystal plasticity theory can be reliably applied in predicting plastic deformation of ceramic at small scales [17]. Lu et al described the mechanical planarization machining of SiC substrates involving the Si face and C face of N-type 4H-SiC, N-type 6H-SiC, and V-type 6H-SiC with a sol-gel polishing pad, the removal mechanism of SiC substrates was investigated by nanoindentation and nanoscratching [18].…”

Section: Introductionmentioning

confidence: 99%

A Nanomechanical Analysis of Deformation Characteristics of 6H-SiC Using an Indenter and Abrasives in Different Fixed Methods

Pan

Yan

et al. 2019

Micromachines

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The super-precise theory for machining single crystal SiC substrates with abrasives needs to be improved for its chemical stability, extremely hard and brittle. A Berkovich indenter was used to carry out a systematic static stiffness indentation experiments on single crystal 6H-SiC substrates, and then these substrates were machined by utilizing fixed, free, and semi-fixed abrasives, and the nanomechanical characteristics and material removal mechanisms using abrasives in different fixed methods were analyzed theoretically. The results indicated that the hardness of C faces and Si faces of single crystal 6H-SiC under 500 mN load were 38.596 Gpa and 36.246 Gpa respectively, and their elastic moduli were 563.019 Gpa and 524.839 Gpa, respectively. Moreover, the theoretical critical loads for the plastic transition and brittle fracture of C face of single crystal 6H-SiC were 1.941 mN and 366.8 mN, while those of Si face were 1.77 mN and 488.67 mN, respectively. The 6H-SiC materials were removed by pure brittle rolling under three-body friction with free abrasives, and the process parameters determined the material removal modes of 6H-SiC substrates by grinding with fixed abrasives, nevertheless, the materials were removed under full elastic-plastic deformation in cluster magnetorheological finishing with semi-fixed abrasives.

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Indentation in single-crystal 6H silicon carbide: Experimental investigations and finite element analysis

Cited by 22 publications

References 29 publications

Physics of molecular deformation mechanism in 6H-SiC

Physics of molecular deformation mechanism in 6H-SiC

Mechanical Behavior Investigation of 4H-SiC Single Crystal at the Micro–Nano Scale

A Nanomechanical Analysis of Deformation Characteristics of 6H-SiC Using an Indenter and Abrasives in Different Fixed Methods

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