https://orcid.org/0000-0002-8626-4431
References
- Tallaire A, Achard J, Silva F, et al. Growth of large size diamond single crystals by plasma assisted chemical vapour deposition: recent achievements and remaining challenges. C R Phys. 2013;14(2–3):169–184.
- Zong WJ, Li ZQ, Sun T, et al. The basic issues in design and fabrication of diamond-cutting tools for ultra-precision and nanometric machining. Int J Mach Tool Manuf. 2010;50(4):411–419.
- Weule H, Hüntrup V, Tritschler H. Micro-cutting of steel to meet new requirements in miniaturization. CIRP Ann. 2001;50(1):61–64.
- Monroy E, Omnès F, Calle F. Wide-bandgap semiconductor ultraviolet photodetectors. Semicond Sci Technol. 2003;18(4):R33–R51.
- Sun L, He X, Lu J. Understanding the mechanical characteristics of nanotwinned diamond by atomistic simulations. Carbon. 2018;127:320–328.
- He G, Xu C, Liu C, et al. Grain size and temperature effects on the indentation induced plastic deformations of nano polycrystalline diamond. Appl Surf Sci. 2019;480:349–360.
- Wu H, Xiao B, Xiao H, et al. Wear characteristics of brazed diamond sheets with different grinding time. Wear. 2019;432:202942.
- Yuan S, Guo X, Huang J, et al. Sub-nanoscale polishing of single crystal diamond (100) and the chemical behavior of nanoparticles during the polishing process. Diam Relat Mater. 2019;100:107528.
- Ollison CD, Brown WD, Malshe AP, et al. A comparison of mechanical lapping versus chemical-assisted mechanical polishing and planarization of chemical vapor deposited (CVD) diamond. Diam Relat Mater. 1999;8(6):1083–1090.
- Yan J, Syoji K, Tamaki JI. Some observations on the wear of diamond tools in ultra-precision cutting of single-crystal silicon. Wear. 2003;255(7–12):1380–1387.
- Padgett CW, Gutt KJ, Whiteside TS. Computational studies on the mechanical properties of diamond nanotoroids. Comput Mater Sci. 2009;46(2):491–494.
- Titkov SV, Mineeva RM, Ryabchikov ID, et al. Sites of the N1 nitrogen paramagnetic centers in natural diamond crystals; dissymmetrization of the structure as a result of plastic deformation. Doklady Earth Sci. 2016;468(1):500–502.
- Man YV M, Pidgornyuk EM, Katrusha AN, et al. Mechanical properties of type IIb synthetic diamond at a temperature of 900°C. J Superhard Mater. 2012;34(5):308–313.
- Sumiya H, Irifune T. Hardness and deformation microstructures of nano-polycrystalline diamonds synthesized from various carbons under high pressure and high temperature. J Mater Res. 2007;22(8):2345–2351.
- Ogata S, Li J. Toughness scale from first principles. J Appl Phys. 2009;106(11):113534.
- Mussi A, Eyidi D, Shiryaev A, et al. TEM observations of dislocations in plastically deformed diamond. Phys Status Solid. 2013;210(1):191–194.
- Regan B, Aghajamali A, Froech J, et al. Plastic deformation of single-crystal diamond nanopillars. Adv Mater. 2020;32(9):1906458.
- Sumiya H, Yamaguchi K, Ogata S. Deformation microstructure of high-quality synthetic diamond crystal subjected to Knoop indentation. Appl Phys Lett. 2006;88(16):161904.
- Banerjee A, Bernoulli D, Zhang H, et al. Ultralarge elastic deformation of nanoscale diamond. Science. 2018;360(6386):300–302.
- Schoor M, Boulliard JC, Gaillou E, et al. Plastic deformation in natural diamonds: rose channels associated to mechanical twinning. Diam Relat Mater. 2016;66:102–106.
- Liu H, Zong W, Cheng X. Origins for the anisotropy of the friction force of diamond sliding on diamond. Tribol Int. 2020;148:106298.
- Zhao L, Alam M, Zhang J, et al. Investigation of the ‘double cross’ splitting mechanism of single-crystal diamond under nanoindentation via molecular dynamics simulation. J Mol Model. 2017;23(10):1610–2940.
- Huang C, Peng X, Yang B, et al. Molecular dynamics simulations for responses of nanotwinned diamond films under nanoindentation. Ceram Int. 2017;43(18):16888–16894.
- Xu C, He G, Liu C, et al. Twin-size effects on the hardness and plastic deformation mechanisms of nanotwinned diamond. Ceram Int. 2018;44(18):22121–22128.
- Plimpton S. Fast parallel algorithms for short-range molecular-dynamics. J Comput Phys. 1995;117(1):1–19.
- Wu Z, Liu W, Zhang L. Effect of structural anisotropy on the dislocation nucleation and evolution in 6H-SiC under nanoindentation. Ceram Int. 2019;45(11):14229–14237.
- Kelchner CL, Plimpton SJ, Hamilton JC. Dislocation nucleation and defect structure during surface indentation. Phys Rev B. 1998;58(17):11085–11088.
- Wang X, Ruslinda AR, Ishiyama Y, et al. Higher coverage of carboxylic acid groups on oxidized single crystal diamond (001). Diam Relat Mater. 2011;20(10):1319–1324.
- de Theije FK, van der Laag NJ, Plomp M, et al. A surface topographic investigation of {001} diamond surfaces etched in oxygen. Philos Mag A. 2000;80(3):725–745.
- Hong D, Zeng W, Yang N, et al. The micro-wear mechanism of diamond during diamond tool fly-cutting KDP (KH2PO4) from first principle calculations. J Mol Model. 2020;26(10):284.
- Liu P, Xie J, Wang A, et al. Molecular dynamics simulation on the deformation mechanism of monocrystalline and nano-twinned TiN under nanoindentation. Mater Chem Phys. 2020;252:123263.
- Doan D, Fang T, Chen T. Influences of grain size and temperature on tribological characteristics of CuAlNi alloys under nanoindentation and nanoscratch. Int J Mech Sci. 2020;185:105865.
- Goel S, Beake B, Chan C, et al. Twinning anisotropy of tantalum during nanoindentation. Mater Sci Eng A. 2015;627:249–261.
- Los JH, Fasolino A. Intrinsic long-range bond-order potential for carbon: performance in Monte Carlo simulations of graphitization. Phys Rev B. 2003;68:24107.
- Barhoumi M, Rocca D, Said M, et al. Elastic and mechanical properties of cubic diamond and silicon using density functional theory and the random phase approximation. Solid State Commun. 2021;324:114136.
- Klein CA. Anisotropy of young modulus and poisson ratio in diamond. Mater Res Bull. 1992;27(12):1407–1414.
- Jian X, Zhang Y. The effect of temperature on the mechanical properties of the diamond coating at the film-substrate interface. Acta Phys Sin. 2015;64(4):046701.
- Bai Q, Wang Z, Guo Y, et al. Graphitization behavior of single crystal diamond for the application in nano-metric cutting. Curr Nanosci. 2018;14(5):377–383.
- Song Y, Nezu K, Park C, et al. Tool wear control in single-crystal diamond cutting of steel by using the ultra-intermittent cutting method. Int J Mach Tool Manuf. 2009;49(3-4):339–343.
- Xiang H, Li H, Fu T, et al. Molecular dynamics simulation of AlN thin films under nanoindentation. Ceram Int. 2017;43(5):4068–4075.
- Domínguez-Gutiérrez FJ, Papanikolaou S, Esfandiarpour A, et al. Nanoindentation of single crystalline Mo: atomistic defect nucleation and thermomechanical stability. Mater Sci Eng A. 2021;826:141912.
- Zhang J, Zhang J, Wang Z, et al. Interaction between phase transformations and dislocations at incipient plasticity of monocrystalline silicon under nanoindentation. Comput Mater Sci. 2017;131:55–61.
- Deng L, Liu Q, Wang X, et al. Load drop and hardness drop during nanoindentation on single-crystal copper investigated by molecular dynamics. Appl Phys A. 2018;124(11):743.
- Li J, Guo J, Luo H, et al. Study of nanoindentation mechanical response of nanocrystalline structures using molecular dynamics simulations. Appl Surf Sci. 2016;364:190–200.
- Zhao L, Song C, Zhang J, et al. Growth of highly oriented graphite by ultraviolet nanosecond pulsed laser ablation of monocrystalline diamond. Appl Surf Sci. 2022;578:151995.
- Wang S, Liu H, Xu L, et al. Investigations of phase transformation in monocrystalline silicon at Low temperatures via nanoindentation. Sci Rep. 2017;7(1):8682.
- Chen J, Shi J, Zhang M, et al. Effect of indentation speed on deformation behaviors of surface modified silicon: a molecular dynamics study. Comput Mater Sci. 2018;155:1–10.
- Nguyen V, Fang T. Phase transformation and subsurface damage formation in the ultrafine machining process of a diamond substrate through atomistic simulation. Sci Rep. 2021;11(1):1–14.