[1] UEHARA Y, MATSUYAMA T, NAKASHIMA T, et al.. Thermal aberration control for low k1 lithography [J]. SPIE, 2007, 6520: 65205V1-65205V11.
[2] NAKASHIMA T, OHMURA Y, OGATA T, et al.. Thermal aberration control in projection lens [J]. SPIE, 2008, 6924: 69241V1-69241V9.
[3] LIU P, SNADJR M, ZHANG X, et al.. A computational method for optical application specific lens control in microlithography [J]. SPIE, 2010, 7640: 76400M1-76400M9.
[4] FUKUHARA K, MIMOTOGI A, KONO T, et al.. Solutions with precise prediction for thermal aberration error in low k1 immersion lithography [J]. SPIE, 2013, 8683: 86830U1-86830U7.
[5] BEKAERT J, ANLOOK L, VANDENBERGHE G, et al.. Characterization and control of dynamic lens heating effects under high volume manufacturing conditions [J]. SPIE, 2011, 7973: 79730V1-79730V11.
[6] OHMURA Y, OGATA T, HIRAYAMA T, et al.. An aberration control of projection optics for multi-patterning lithography [J]. SPIE, 2011, 7973: 79730W1-79730W11.
[7] MULKENS J, KLERK J, LEENDERS M, et al.. Latest developments on immersion exposure systems [J]. SPIE, 2008, 6924: 69241P1-69241P12.
[8] STAALS F, ANDRYZHYIEUSKAYA A, BAKKER H, et al.. Advanced wavefront engineering for improved imaging and overlay applications on a 1.35 NA immersion scanner [J]. SPIE, 2011, 7973: 79731G1-79731G13.
[9] YOSHIHARA T, SUKEGAWA T, YABU N, et al.. Advanced aberration control in projection optics for double pattering [J]. Optical Microlithography XXII, SPIE, 2009, 7274: 72741L1-72741L9.
[10] CHEN H, YANG H J, YU X F, et al.. Simulated and experimental study of laser-beam induced thermal aberrations in precision optical systems [J]. Applied Optics, 2013, 52(18): 4370-4376.
[11] DOYLE K, GENBERG V, MICHELS G. Integrated Optomechanical Analysis [M]. Washington: SPIE Press, 2002.
[12] YU X F, NI M Y, ZHANG W, et al.. Analysis and experiments of the thermal-optical performance for a kinematically mounted lens element [J]. Applied Optics, 2014, 53(18): 4370-4376.
