Experimental power spectral density analysis for mid- to high-spatial frequency surface error control.

The control of surface errors as a function of spatial frequency is critical during the fabrication of modern optical systems. A large-scale surface figure error is controlled by a guided removal process, such as computer-controlled optical surfacing. Smaller-scale surface errors are controlled by polishing process parameters. Surface errors of only a few millimeters may degrade the performance of an optical system, causing background noise from scattered light and reducing imaging contrast for large optical systems. Conventionally, the microsurface roughness is often given by the root mean square at a high spatial frequency range, with errors within a 0.5×0.5  mm local surface map with 500×500 pixels. This surface specification is not adequate to fully describe the characteristics for advanced optical systems. The process for controlling and minimizing mid- to high-spatial frequency surface errors with periods of up to ∼2-3  mm was investigated for many optical fabrication conditions using the measured surface power spectral density (PSD) of a finished Zerodur optical surface. Then, the surface PSD was systematically related to various fabrication process parameters, such as the grinding methods, polishing interface materials, and polishing compounds. The retraceable experimental polishing conditions and processes used to produce an optimal optical surface PSD are presented.

[1]  P E Miller,et al.  Effect of rogue particles on the sub-surface damage of fused silica during grinding/polishing , 2007 .

[2]  Dongxu Wu,et al.  Influences of grinding and polishing parameters on the quality of super smooth surface , 2014, Other Conferences.

[3]  J. Stover Optical Scattering: Measurement and Analysis , 1990 .

[4]  Hubert M. Martin,et al.  Process optimization for polishing large aspheric mirrors , 2014, Astronomical Telescopes and Instrumentation.

[5]  Toshio Kasai,et al.  Improvement of Conventional Polishing Conditions for Obtaining Super Smooth Surfaces of Glass and Metal Works , 1990 .

[6]  Dae Wook Kim,et al.  Rigid conformal polishing tool using non-linear visco-elastic effect. , 2010, Optics express.

[7]  Bin Ma,et al.  Fabrication of supersmooth optical elements with low surface and subsurface damage , 2012, Other Conferences.

[8]  Martin Schäfer,et al.  Game-changing approaches to affordable advanced lightweight mirrors: Extreme Zerodur lightweighting and relief from the classical polishing parameter constraint , 2011, Optical Engineering + Applications.

[9]  Jianbin Luo,et al.  CMP of hard disk substrate using a colloidal SiO2 slurry: preliminary experimental investigation , 2004 .

[10]  Ci Song,et al.  Combined fabrication process for high-precision aspheric surface based on smoothing polishing and magnetorheological finishing , 2014, Other Conferences.

[11]  L. Cook Chemical processes in glass polishing , 1990 .

[12]  James E. Harvey,et al.  Calculating BRDFs from surface PSDs for moderately rough optical surfaces , 2009, Optical Engineering + Applications.

[13]  F. W. Preston The Theory and Design of Plate Glass Polishing Machines , 1927 .

[14]  Robert E. Parks Specifications: figure and finish are not enough , 2008, Optical Engineering + Applications.

[15]  J. Ruan,et al.  Lapping and polishing process for obtaining super-smooth surfaces of quartz crystal , 2003 .

[16]  Peter Hartmann,et al.  ZERODUR® glass ceramics for high stress applications , 2009, Optical Engineering + Applications.

[17]  James H. Burge,et al.  Super-smooth optical fabrication controlling high-spatial frequency surface irregularity , 2013, Optics & Photonics - Optical Engineering + Applications.

[18]  Ivana Poláková,et al.  Super-polishing of Zerodur aspheres by means of conventional polishing technology , 2015, Other Conferences.

[19]  T. Izumitani,et al.  Polishing Mechanism of Optical Glass , 1970 .

[20]  Birgit E. Gillman,et al.  Fun facts about pitch and the pitfalls of ignorance , 1999, Optics + Photonics.

[21]  J. S. Taylor,et al.  Efficient polishing of aspheric optics , 1997 .

[22]  James H. Burge,et al.  New approach for pre-polish grinding with low subsurface damage , 2011, Optical Engineering + Applications.

[23]  David D. Walker,et al.  Robotic automation in computer controlled polishing , 2016 .

[24]  Phillip C. Baker,et al.  Optical Polishing Of Metals , 1982, Optics & Photonics.

[25]  Minghong Yang,et al.  Polishing performances of different optics with different size powder and different pH value slurries during CMP polishing , 2015, SPIE Optifab.

[26]  H. Eyring Viscosity, Plasticity, and Diffusion as Examples of Absolute Reaction Rates , 1936 .

[27]  A. Kaller Properties of polishing media for precision optics , 1998 .

[28]  Peter Hartmann,et al.  Four decades of ZERODUR mirror substrates for astronomy , 2009, International Symposium on Advanced Optical Manufacturing and Testing Technologies (AOMATT).

[29]  M. J. Cumbo,et al.  Slurry particle size evolution during the polishing of optical glass. , 1995, Applied optics.