Ramos AC et al (2012) Characterization of the transition from ploughing to cutting in micro machining and evaluation of the minimum thickness of cut. J Mater Process Technol 212(3):594–600

Kong M et al (2006) A study of materials swelling and recovery in single-point diamond turning of ductile materials. J Mater Process Technol 180(1-3):210–215

Tian F, Yin Z, Li S (2016) Theoretical and experimental investigation on modeling of surface topography influenced by the tool-workpiece vibration in the cutting direction and feeding direction in single-point diamond turning. Int J Adv Manuf Technol 86(9-12):2433–2439

Siddhpura A, Paurobally R (2013) A review of flank wear prediction methods for tool condition monitoring in a turning process. Int J Adv Manuf Technol 65(1-4):371–393

Kishawy H, Haglund A, Balazinski M (2006) Modelling of material side flow in hard turning. CIRP Annals-Manufacturing Technology 55(1):85–88

Taniguchi N (1994) The state of the art of the nanotechnology for processing of ultraprecision and ultrafine products. Precis Eng 16:5

Black JT (1971) On the fundamental mechanism of large strain plastic deformation: Electron microscopy of metal cutting chips. J Eng Ind 93(2):507–526

McKeown P et al (1986) The design and development of a large ultra-precision CNC diamond turning machine. MATER MANUF PROCESS 1(1):133–157

Zhang G, S. To, Xiao G (2014) Novel tool wear monitoring method in ultra-precision raster milling using cutting chips. Precis Eng 38(3):555–560

Kitahara H et al (2001) Mechanical behavior of single crystalline and polycrystalline silicon carbides evaluated by Vickers indentation. J Ceram Soc Jpn 109(1271):602–606

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Zhou M and Lee W (1993) A microplasticity analysis of shear zone formation in single crystal cutting, in Advances in Engineering Plasticity and Its Applications, Elsevier. p. 875-880.

Fang F, Wu H, Liu Y (2005) Modelling and experimental investigation on nanometric cutting of monocrystalline silicon. Int J Mach Tools Manuf 45(15):1681–1686

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Pavel R et al (2005) Effect of tool wear on surface finish for a case of continuous and interrupted hard turning. J Mater Process Technol 170(1-2):341–349

Senthil Kumar A et al (2014) Fast and fine tool servo for ultraprecision machining in comprehensive materials processing. Rahman M, editor 11:61–88

Lee W, Cheung C, S. To (1999) Materials induced vibration in ultra-precision machining. J Mater Process Technol 89:318–325

Syn C, Taylor J, Donaldson R (1987) Diamond tool wear vs. cutting distance on electroless nickel mirrors. in Ultraprecision Machining and Automated Fabrication of Optics. Int Soc Opt Photonics

Zarudi I, Nguyen T, Zhang LC (2005) Effect of temperature and stress on plastic deformation in monocrystalline silicon induced by scratching. Appl Phys Lett 86(1):011922

Fang, F., X. Liu, and L. Lee, Micro-machining of optical glasses—a review of diamond-cutting glasses. Sadhana, 2003. 28(5): p. 945-955.

Zong W et al (2014) Conservation law of surface roughness in single point diamond turning. Int J Mach Tools Manuf 84:58–63

To S, Lee W, Cheung C (2003) Orientation changes of aluminium single crystals in ultra-precision diamond turning. J Mater Process Technol 140(1-3):346–351

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Zhou ZM et al (2012) Tool wear of diamond tools in ultrasonic vibration turning titanium alloys. in Applied Mechanics and Materials. Trans Tech Publ

Dogra, M., V. Sharma, and J. Dureja, Effect of tool geometry variation on finish turning-A Review. J Eng Sci Technol Rev, 2011. 4(1).

Cheung C, Lee W (2001) Characterisation of nanosurface generation in single-point diamond turning. Int J Mach Tools Manuf 41(6):851–875

Hatefi, S., Abou-El-Hossein, K. Review of single-point diamond turning process in terms of ultra-precision optical surface roughness. Int J Adv Manuf Technol 106, 2167–2187 (2020). https://doi.org/10.1007/s00170-019-04700-3

Zhang S et al (2012) Dynamic characteristics of an aerostatic bearing spindle and its influence on surface topography in ultra-precision diamond turning. Int J Mach Tools Manuf 62:1–12

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Zhang S et al (2016) A review of fly cutting applied to surface generation in ultra-precision machining. Int J Mach Tools Manuf 103:13–27

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Zhang S, S. To (2013) A theoretical and experimental study of surface generation under spindle vibration in ultra-precision raster milling. Int J Mach Tools Manuf 75:36–45

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Zhang S, S. To (2013) A theoretical and experimental investigation into multimode tool vibration with surface generation in ultra-precision diamond turning. Int J Mach Tools Manuf 72:32–36

Yip W, S. To (2017) Reduction of material swelling and recovery of titanium alloys in diamond cutting by magnetic field assistance. J Alloys Compd 722:525–531

Kim D-S, Chang I-C, Kim S-W (2002) Microscopic topographical analysis of tool vibration effects on diamond turned optical surfaces. Precis Eng 26(2):168–174

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Zhang S, Li J, Wang Y (2012) Tool life and cutting forces in end milling Inconel 718 under dry and minimum quantity cooling lubrication cutting conditions. J Clean Prod 32:81–87

Wang C-C, Jang M-J (2004) and C.o.-K. Chen, Non-linear dynamic analysis of a flexible rotor supported by self-acting gas journal bearings. Proc Inst Mech Eng C J Mech Eng Sci 218(12):1527–1538

Arefin S et al (2007) The upper bound of tool edge radius for nanoscale ductile mode cutting of silicon wafer. Int J Adv Manuf Technol 31(7-8):655

Zhang S et al (2014) Micro-structural changes of Zn–Al alloy influencing micro-topographical surface in micro-cutting. Int J Adv Manuf Technol 72(1-4):9–15

Fuller DD (1969) A review of the state-of-the-art for the design of self-acting gas-lubricated bearings. J Lubr Technol 91(1):1–16

Huang P, Lee W (2016) Cutting force prediction for ultra-precision diamond turning by considering the effect of tool edge radius. Int J Mach Tools Manuf 109:1–7

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Chen H, et al. (2011) Effect of crystallographic orientation on cutting forces and surface finish in ductile cutting of KDP crystals. machining science and technology 15(2): p. 231-242.

Shaw MC (2005) Metal cutting principles–Oxford series on advanced manufacturing. Publ, Oxford University Press, New York (USA)

Shimada S et al (1993) Feasibility study on ultimate accuracy in microcutting using molecular dynamics simulation. CIRP Ann 42(1):91–94

To S, Cheung C, Lee W (2001) Influence of material swelling on surface roughness in diamond turning of single crystals. Mater Sci Technol 17(1):102–108

Xu S et al (2017) Recent advances in ultrasonic-assisted machining for the fabrication of micro/nano-textured surfaces. Front Mech Eng 12(1):33–45

Yue X et al (2017) Effect of cutting edge radius on surface roughness in diamond tool turning of transparent MgAl2O4 spinel ceramic. Opt Mater 71:129–135

Goel S et al (2013) Brittle–ductile transition during diamond turning of single crystal silicon carbide. Int J Mach Tools Manuf 65:15–21

Lai M et al (2017) Fundamental investigation on partially overlapped nano-cutting of monocrystalline germanium. Precis Eng 49:160–168

Ko TJ, Cho DW, Lee JM (1992) Fuzzy pattern recognition for tool wear monitoring in diamond turning. CIRP Annals-Manufacturing Technology 41(1):125–128

Image

Shimada S et al (2004) Thermo-chemical wear mechanism of diamond tool in machining of ferrous metals. CIRP Ann 53(1):57–60

Thakur A, Gangopadhyay S (2016) State-of-the-art in surface integrity in machining of nickel-based super alloys. Int J Mach Tools Manuf 100:25–54

Sata T et al (1985) Analysis of surface roughness generation in turning operation and its applications. CIRP Annals-Manufacturing Technology 34(1):473–476

Lasercutting fiber

Yuan Z, Zhou M, Dong S (1996) Effect of diamond tool sharpness on minimum cutting thickness and cutting surface integrity in ultraprecision machining. J Mater Process Technol 62(4):327–330

Zhao T et al (2017) Effect of cutting edge radius on surface roughness and tool wear in hard turning of AISI 52100 steel. Int J Adv Manuf Technol 91(9-12):3611–3618

Wang C-C, Yau H-T (2010) Theoretical analysis of high speed spindle air bearings by a hybrid numerical method. Appl Math Comput 217(5):2084–2096

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Singh R, Khamba J (2006) Ultrasonic machining of titanium and its alloys: a review. J Mater Process Technol 173(2):125–135

Song Y et al (2009) Tool wear control in single-crystal diamond cutting of steel by using the ultra-intermittent cutting method. Int J Mach Tools Manuf 49(3-4):339–343

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Ostasevicius V et al (2010) An approach based on tool mode control for surface roughness reduction in high-frequency vibration cutting. J Sound Vib 329(23):4866–4879

Moriwaki T (1989) Machinability of copper in ultra-precision micro diamond cutting. CIRP Annals-Manufacturing Technology 38(1):115–118

Yan J, Syoji K (2003) and J.i. Tamaki, Some observations on the wear of diamond tools in ultra-precision cutting of single-crystal silicon. Wear 255(7-12):1380–1387

Donaldson, R., et al., Minimum thickness of cut in diamond turning of electroplated copper. UCRL-97606, 1987. 1: p. 987.

Goel S et al (2013) Anisotropy of single-crystal 3C–SiC during nanometric cutting. Model Simul Mater Sci Eng 21(6):065004

Brinksmeier E, Gläbe R, Schönemann L (2012) Review on diamond-machining processes for the generation of functional surface structures. CIRP J Manuf Sci Technol 5(1):1–7

Sun X and Cheng K (2015) Chapter 2 - micro-/nano-machining through Mechanical Cutting A2 - Qin, Yi, in Micromanufacturing Engineering and Technology (Second Edition), William Andrew Publishing: Boston. p. 35-59.

Babitsky V, Astashev V (2007) Nonlinear dynamics and control of ultrasonically assisted machining. J Vib Control 13(5):441–460

Lawson BL, Kota N, Ozdoganlar OB (2008) Effects of crystallographic anistropy on orthogonal micromachining of single-crystal aluminum. J Manuf Sci Eng 130(3):031116–031116-11

Fan Y et al (2015) New observations on tool wear mechanism in machining Inconel 718 under water vapor+ air cooling lubrication cutting conditions. J Clean Prod 90:381–387

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Cheung C, Lee W (2000) A theoretical and experimental investigation of surface roughness formation in ultra-precision diamond turning. Int J Mach Tools Manuf 40(7):979–1002

Bulla B, Klocke F, Dambon O (2015) Influence of ultrasonic assisted processing on the ductility of binderless tungsten carbide. in Key Engineering Materials. Trans Tech Publ

Yan J, Zhang Z, Kuriyagawa T (2009) Mechanism for material removal in diamond turning of reaction-bonded silicon carbide. Int J Mach Tools Manuf 49(5):366–374

Nath C, Rahman M, Neo KS (2009) Enhancing the performance of polycrystalline diamond tools for machining WC by ultrasonic elliptical vibration cutting method. Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 27(3):1241–1246

Abhang L, Hameedullah M (2014) Parametric investigation of turning process on en-31 steel. Procedia Mater Sci 6:1516–1523

Takasu S et al (1985) Influence of study vibration with small amplitude upon surface roughness in diamond machining. CIRP Annals-Manufacturing Technology 34(1):463–467

Sreejith P (2008) Machining of 6061 aluminium alloy with MQL, dry and flooded lubricant conditions. Mater Lett 62(2):276–278

Arif M et al (2013) A predictive model of the critical undeformed chip thickness for ductile–brittle transition in nano-machining of brittle materials. Int J Mach Tools Manuf 64:114–122

Wang C et al (2017) Effect of different oil-on-water cooling conditions on tool wear in turning of compacted graphite cast iron. J Clean Prod 148:477–489

Wojciechowski S, Mrozek K (2017) Mechanical and technological aspects of micro ball end milling with various tool inclinations. Int J Mech Sci 134:424–435

Sarıkaya M, Yılmaz V, Güllü A (2016) Analysis of cutting parameters and cooling/lubrication methods for sustainable machining in turning of Haynes 25 superalloy. J Clean Prod 133:172–181

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Ikawa N et al (1991) Ultraprecision metal cutting—the past, the present and the future. CIRP Annals-Manufacturing Technology 40(2):587–594

Wang SJ, S. To, Cheung CF (2013) An investigation into material-induced surface roughness in ultra-precision milling. Int J Adv Manuf Technol 68(1):607–616

Zong W et al (2013) Finite element simulation of diamond tool geometries affecting the 3D surface topography in fly cutting of KDP crystals. Int J Adv Manuf Technol 68(9-12):1927–1936

These cookies help us measure the website’s performance and improve your experience. In using performance cookies, we do not store personal data and only use the information collected through these cookies in aggregated and anonymized form.

Vyroubal J (2012) Compensation of machine tool thermal deformation in spindle axis direction based on decomposition method. Precis Eng 36(1):121–127

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Nath C, Lim G, Zheng H (2012) Influence of the material removal mechanisms on hole integrity in ultrasonic machining of structural ceramics. Ultrasonics 52(5):605–613

Malekian M et al (2012) Modeling of minimum uncut chip thickness in micro machining of aluminum. J Mater Process Technol 212(3):553–559

Suh CS and Liu M.-K (2013) Control of cutting vibration and machining instability: a time-frequency approach for precision, micro and nano machining. John Wiley & Sons.

To S, Lee WB, Chan CY (1997) Ultraprecision diamond turning of aluminium single crystals. J Mater Process Technol 63(1):157–162

Sze Y.-k (2006) The effect of preferred orientation in the single point diamond turning of polycrystalline materials, The Hong Kong Polytechnic University

Cutting fiberoptic cable

Wang C-C (2006) Nonlinear dynamic behavior and bifurcation analysis of a rigid rotor supported by a relatively short externally pressurized porous gas journal bearing system. Acta Mech 183(1-2):41–60

Xu F, Fang F, Zhu Y, Zhang X (2017) Study on crystallographic orientation effect on surface generation of aluminum in nano-cutting. Nanoscale Res Lett 12(1):289

Liu K, Melkote SN (2006) Effect of plastic side flow on surface roughness in micro-turning process. Int J Mach Tools Manuf 46(14):1778–1785

Cheung C-F, Lee W-B (2000) An investigation of cutting dynamics in single point diamond turning. JSME Int J Ser C Mech Syst Mach Elem Manuf 43(1):116–126

Wang S et al (2010) A study of the cutting-induced heating effect on the machined surface in ultra-precision raster milling of 6061 Al alloy. Int J Adv Manuf Technol 51(1-4):69–78

Câmara MA et al (2016) Determination of the critical undeformed chip thickness in micromilling by means of the acoustic emission signal. Precis Eng 46:377–382

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Zhang S, S. To (2013) The effects of spindle vibration on surface generation in ultra-precision raster milling. Int J Mach Tools Manuf 71:52–56

Ding X, Rahman M (2012) A study of the performance of cutting polycrystalline Al 6061 T6 with single crystalline diamond micro-tools. Precis Eng 36(4):593–603

Cheung CF, Lee WB (2000) A multi-spectrum analysis of surface roughness formation in ultra-precision machining. Precis Eng 24(1):77–87

Wang H et al (2011) Dynamic modelling of shear band formation and tool-tip vibration in ultra-precision diamond turning. Int J Mach Tools Manuf 51(6):512–519

Kishawy H, Elbestawi M (1999) Effects of process parameters on material side flow during hard turning. Int J Mach Tools Manuf 39(7):1017–1030

Image

He CL, Zong WJ, Zhang JJ (2018) Influencing factors and theoretical modeling methods of surface roughness in turning process: state-of-the-art. Int J Mach Tools Manuf 129:15–26

Lee W et al (2003) Effect of material anisotropy on shear angle prediction in metal cutting—a mesoplasticity approach. Int J Mech Sci 45(10):1739–1749

Lane BM, Dow TA, Scattergood R (2013) Thermo-chemical wear model and worn tool shapes for single-crystal diamond tools cutting steel. Wear 300(1-2):216–224

Lee W and Cheung BC (2003) Surface generation in ultra-precision diamond turning: modelling and practices. Vol. 12. : John Wiley & Sons.

Xin, X. (1991) Ultra-high-precision machining techniques: applications and current status, FOREIGN TECHNOLOGY DIV WRIGHT-PATTERSON AFB OH

Sun S, Brandt M, Dargusch M (2009) Characteristics of cutting forces and chip formation in machining of titanium alloys. Int J Mach Tools Manuf 49(7-8):561–568

Yuan Z et al (1994) Effect of crystallographic orientation on cutting forces and surface quality in diamond cutting of single crystal. CIRP Annals-Manufacturing Technology 43(1):39–42

Arunachalam R, Mannan M, Spowage A (2004) Residual stress and surface roughness when facing age hardened Inconel 718 with CBN and ceramic cutting tools. Int J Mach Tools Manuf 44(9):879–887

Chapman, G., Ultra-precision machining systems; an enabling technology for perfect surfaces. Moore Nanotechnology Systems, 2004.

Li Y et al (2018) Molecular dynamics investigation of residual stress and surface roughness of cerium under diamond cutting. Micromachines 9(8):386

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Cheung C, Lee W (2000) Study of factors affecting the surface quality in ultra-precision diamond turning. Mater Manuf Process 15(4):481–502

Marsh, E., et al. (2005) The effects of spindle dynamics on precision flycutting. in Proceedings of the American society for precision engineering 2005 annual meeting. Citeseer.

Moriwaki T, Shamoto E, Inoue K (1992) Ultraprecision ductile cutting of glass by applying ultrasonic vibration. CIRP Ann 41(1):141–144

Goel S et al (2015) Diamond machining of silicon: a review of advances in molecular dynamics simulation. Int J Mach Tools Manuf 88:131–164

Kong L et al (2010) Modeling of ultra-precision raster milling and characterization of optical freeform surfaces. Dept. of Industrial and Systems Engineering. The Hong Kong Polytechnic University: Hong Kong.

M'Saoubi R et al (2015) High performance cutting of advanced aerospace alloys and composite materials. CIRP Ann 64(2):557–580

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Lucca DA, Seo Y, Komanduri R (1993) Effect of tool edge geometry on energy dissipation in ultraprecision machining. CIRP Ann 42(1):83–86

Bhattacharya B, Patten JA, and Jacob J (2006) Single point diamond turning of CVD coated silicon carbide. in ASME 2006 International Manufacturing Science and Engineering Conference. Am Soc Mech Eng

Gläbe R and Riemer O (2010) Diamond machining of micro-optical components and structures. in Micro-Optics 2010. International Society for Optics and Photonics.

Tauhiduzzaman M, Veldhuis S (2014) Effect of material microstructure and tool geometry on surface generation in single point diamond turning. Precis Eng 38(3):481–491

We use analytical cookies to measure how you use our website so we may continually improve it. For example, these cookies allow us to recognize and count the number of visitors to our website and see which pages visitors view.

Zou P et al (2015) Experimental investigation of ultrasonic vibration assisted turning of 304 austenitic stainless steel. Shock Vib 2015

Lee WB, Cheung CF, S. To (2003) A mesoplasticitiy analysis of cutting friction in ultra-precision machining. J Mater Process Technol 140(1):292–297

Cheung C, S. To, Lee W (2002) Anisotropy of surface roughness in diamond turning of brittle single crystals. Mater Manuf Process 17(2):251–267

Wang H, S. To, Chan C (2013) Investigation on the influence of tool-tip vibration on surface roughness and its representative measurement in ultra-precision diamond turning. Int J Mach Tools Manuf 69:20–29

Zhou M et al (2002) Brittle–ductile transition in the diamond cutting of glasses with the aid of ultrasonic vibration. J Mater Process Technol 121(2-3):243–251

Li L, Collins JSA, Yi AY (2010) Optical effects of surface finish by ultraprecision single point diamond machining. J Manuf Sci Eng 132(2):021002 -021002-9

Chin J-H, Chen C-C (1993) A study of stick-slip motion and its influence on the cutting process. Int J Mech Sci 35(5):353–370

Moriwaki T, Horiuchi A, Okuda K (1990) Effect of cutting heat on machining accuracy in ultra-precision diamond turning. CIRP Ann 39(1):81–84

Zhang X et al (2018) Rotating-tool diamond turning of Fresnel lenses on a roller mold for manufacturing of functional optical film. Precis Eng 51:445–457

Li L et al (2006) Fabrication of diffractive optics by use of slow tool servo diamond turning process. Opt Eng 45(11):113401

Chen YP et al (2008) FINITE ELEMENT MODELLING OF MICRO-CUTTING PROCESSES FROM CRYSTAL PLASTICITY. Int J Mod Phys B 22(31n32):5943–5948

Overcash JL, Cuttino JF (2009) Design and experimental results of a tunable vibration turning device operating at ultrasonic frequencies. Precis Eng 33(2):127–134

Xu SL, et al. (2013) Surface textures fabrication on zirconia ceramics by 3D ultrasonic vibration assisted slant feed grinding. in Advanced Materials Research. Trans Tech Publ.

Xu S, et al. (2013) B013 surface texturing and wettability evaluation of zirconia ceramics. in Proceedings of International Conference on Leading Edge Manufacturing in 21st century: LEM21 2013.7. The Japan Society of Mechanical Engineers.

Ramesh R, Mannan M, Poo A (2000) Error compensation in machine tools—a review: Part II: thermal errors. Int J Mach Tools Manuf 40(9):1257–1284

Jasinevicius R et al (2003) Influence of the mechanical and metallurgical state of an Al-Mg alloy on the surface integrity in ultraprecision machining. J Braz Soc Mech Sci Eng 25(3):222–228

Maurotto A, Wickramarachchi C (2016) Experimental investigations on effects of frequency in ultrasonically-assisted end-milling of AISI 316L: a feasibility study. Ultrasonics 65:113–120

Lee WB, Zhou M (1993) A theoretical analysis of the effect of crystallographic orientation on chip formation in micromachining. Int J Mach Tools Manuf 33(3):439–447

Yingfei G, Jiuhua X, Hui Y (2010) Diamond tools wear and their applicability when ultra-precision turning of SiCp/2009Al matrix composite. Wear 269(11-12):699–708

Shi J, Wang Y, Yang X (2013) Nano-scale machining of polycrystalline coppers - effects of grain size and machining parameters. Nanoscale Res Lett 8(1):500

Wang S, et al. (2011) Modelling and optimization of cutting strategy and surface generation in ultra-precision raster milling. Dept. of Industrial and Systems Engineering, The Hong Kong Polytechnic University: Hong Kong

Takeuchi Y et al (2000) Development of a 5-axis control ultraprecision milling machine for micromachining based on non-friction servomechanisms. CIRP Annals-Manufacturing Technology 49(1):295–298

Xu F, Fang F, Zhang X (2018) Effects of recovery and side flow on surface generation in nano-cutting of single crystal silicon. Comput Mater Sci 143:133–142

He C, Zong W, Sun T (2016) Origins for the size effect of surface roughness in diamond turning. Int J Mach Tools Manuf 106:22–42

Zhang S, S. To, Wang H (2013) A theoretical and experimental investigation into five-DOF dynamic characteristics of an aerostatic bearing spindle in ultra-precision diamond turning. Int J Mach Tools Manuf 71:1–10

Izman S, Venkatesh V (2007) Gelling of chips during vertical surface diamond grinding of BK7 glass. J Mater Process Technol 185(1-3):178–183

The focal length of a microscope objective is typically between 2 mm and 40 mm. However, that parameter is often considered as less important, since ...

Zhang S-J et al (2012) Novel auto-regressive measurement of diamond tool wear in ultra-precision raster milling. Int J Precis Eng Manuf 13(9):1661–1670

Vivekananda K, Arka G, Sahoo S (2014) Finite element analysis and process parameters optimization of ultrasonic vibration assisted turning (UVT). Procedia Mater Sci 6:1906–1914

Patten J, Gao W, Yasuto K (2005) Ductile regime nanomachining of single-crystal silicon carbide. J Manuf Sci Eng 127(3):522–532

Chan KC et al (2001) A theoretical and experimental investigation of surface generation in diamond turning of an Al6061/SiCp metal matrix composite. Int J Mech Sci 43(9):2047–2068

Wang H et al (2010) A study of regularly spaced shear bands and morphology of serrated chip formation in microcutting process. Scr Mater 63(2):227–230

Yin Z, S. To, Lee W (2009) Wear characteristics of diamond tool in ultraprecision raster milling. Int J Adv Manuf Technol 44(7-8):638–647

Weck M, Modemann K (1988) Surface quality as a function of static and dynamic machine-tool behaviour during the cutting process. Surface Topography 1:255–265

Miao J et al (2017) Investigation on the generation of the medium-frequency waviness error in flycutting based on 3D surface topography. Int J Adv Manuf Technol 90(1-4):667–675

Lu H et al (2014) Modeling and machining evaluation of microstructure fabrication by fast tool servo-based diamond machining. Precis Eng 38(1):212–216

NdNd3+3+:YAG:YAG laser are pulse-compressed and frequency doubled. Mode locking is monitored by a fastfast photodiode, and the cw frequency-doubled power is ...

An C et al (2010) Modeling of dynamic characteristic of the aerostatic bearing spindle in an ultra-precision fly cutting machine. Int J Mach Tools Manuf 50(4):374–385

Larson RH, Richardson HH (1962) A preliminary study of whirl instability for pressurized gas bearings. J Basic Eng 84(4):511–518

Zhang, S., et al., A study of cutting force variation influencing surface topography in ultra-precision machining. 2010.

Sato M, Kato Y, Tuchiya K (1978) Effects of material anisotropy upon the cutting mechanism. Trans Jpn Inst Metals 19(10):530–536

Bulla B, Klocke F, Dambon O (2012) Analysis on ductile mode processing of binderless, nano crystalline tungsten carbide through ultra precision diamond turning. J Mater Process Technol 212(5):1022–1029

To S et al (2009) Microstructural characterization of an ultra-precision-machined surface of a Zn–Al alloy. J Micromech Microeng 19(5):054005

Grabchenko AI, Mamalis AG, Lavrynenko SN (2006) Microwear of cutting tool in ultraprecision single-point diamond machining of polymers for optical and bioengineering application. Int J Nanomanuf 1(2):181–188

Ding X et al (2012) A study of the cutting performance of poly-crystalline oxygen free copper with single crystalline diamond micro-tools. Precis Eng 36(1):141–152

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Blackley W, Scattergood R (1991) Ductile-regime machining model for diamond turning of brittle materials. Precis Eng 13(2):95–103

Zhang S et al (2015) A review of surface roughness generation in ultra-precision machining. Int J Mach Tools Manuf 91:76–95

Uddin MS et al (2004) Effect of crystallographic orientation on wear of diamond tools for nano-scale ductile cutting of silicon. Wear 257(7-8):751–759

Zhang S, Zhang H, Zong W (2019) Modeling and simulation on the effect of tool rake angle in diamond turning of KDP crystal. J Mater Process Technol 273:116259

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Li Z et al (2018) Ultrasonically assisted single point diamond turning of optical mold of tungsten carbide. Micromachines 9(2):77

Cao J et al (2014) Material removal behavior in ultrasonic-assisted scratching of SiC ceramics with a single diamond tool. Int J Mach Tools Manuf 79:49–61

Goel S et al (2013) Brittle-ductile transition during diamond turning of single crystal silicon carbide. Int J Mach Tools Manuf Int J Mach Tools Manuf 65:15–21

Wang C-C (2008) Theoretical and nonlinear behavior analysis of a flexible rotor supported by a relative short herringbone-grooved gas journal-bearing system. Physica D: Nonlinear Phenomena 237(18):2282–2295

Furukawa Y, Moronuki N (1988) Effect of material properties on ultra precise cutting processes. CIRP Annals-Manufacturing Technology 37(1):113–116

Wang C-C et al (2007) Theoretical analysis of the non-linear behavior of a flexible rotor supported by herringbone grooved gas journal bearings. Tribol Int 40(3):533–541

Wang S et al (2015) An investigation on surface finishing in ultra-precision raster milling of aluminum alloy 6061. Proc Inst Mech Eng B J Eng Manuf 229(8):1289–1301

Astashev VK and Babitsky VI (2007) Ultrasonic processes and machines: dynamics, control and applications. Springer Science & Business Media.

Ultra-precision machining is the recent realm subsequent to conventional precision machining processes. Recently, achieving nanoscale features on products has become important in manufacturing of critical components. One of the main objectives in advanced manufacturing of optics is to reach ultimately high precision in accuracy of optical surface generation. Through further development of computer numerical controlled machinery technology, single-point diamond turning (SPDT) has evolved rapidly and became a key step in the process chain of nano-machining. In SPDT, advanced and competitive technology for optical surface generation combined with ultra-precision fixtures and accurate metrological systems, high-precision surface machining with scales down to 1 nanometer, even less than 1 nanometer, are successfully achieved. Different engineering applications including medical, dental, defense, aerospace, computer science, and electronic components demand extreme smoothness and optical quality of the machined surfaces. However, there are limitations and drawbacks in SPDT process and surface generation using this technology. Different factors may significantly influence turning conditions, affect surface generation, and limit the outcome of the process. This paper attempts to provide a review of ultra-precision SPDT: technology and characteristics, manufacturing process, applications, machinable materials, and surface generation. Subsequently, influencing factors on surface generation are introduced and comprehensively discussed. Studying influencing factors on surface generation could enable setting optimized sets of machining factors and providing best possible machining conditions for generating high quality optical surfaces. Furthermore, limitations and drawbacks of standard structure SPDT process is discussed. Although a number of published studies have attempted to provide a good perspective of the SPDT process by looking into the effect of influencing factors on surface generation and existing limitations, more investigation needs to be undertaken to discover all destructive effects, origins, and influences in order to further extend the machinability of materials, reduce side effects, and improve the outcome of SPDT.

Wang H et al (2010) A theoretical and experimental investigation of the tool-tip vibration and its influence upon surface generation in single-point diamond turning. Int J Mach Tools Manuf 50(3):241–252