[1] Elder F R, Gurewitsch A M, Langmuir R V, et al. Radiation from electrons in a synchrotron[J]. Physical Review, 71, 829(1947).

[2] Zhao Zhentang. Principles key technologies of advanced Xray light source accelerats[M]. Shanghai: Shanghai Jiao Tong University Press, 2021

[3] Hettel R. DLSR design and plans: an international overview[J]. Journal of Synchrotron Radiation, 21, 843-855(2014).

[4] Jankowiak A, Wüstefeld G. Low-α operation of BESSY II and future plans for an alternating bunch length scheme BESSY^VSR[J]. Synchrotron Radiation News, 26, 22-24(2013).

[5] Byrd J M, Loftsdóttir , Venturini M, et al. Stable CSR in stage rings: a model[R]. LBNL56777, 2005.

[6] Byrd J M, Leemans W P, Loftsdottir A, et al. Observation of broadband self-amplified spontaneous coherent terahertz synchrotron radiation in a storage ring[J]. Physical Review Letters, 89, 224801(2002).

[7] Venturini M, Warnock R. Bursts of coherent synchrotron radiation in electron storage rings: a dynamical model[J]. Physical Review Letters, 89, 224802(2002).

[8] Schoenlein R W, Chattopadhyay S, Chong H H W, et al. Generation of femtosecond pulses of synchrotron radiation[J]. Science, 287, 2237-2240(2000).

[9] Ingold G, Beaud P, Johnson S L, et al. Technical report: FEMTO: a sub-ps tunable hard X-ray undulator source for laser/X-ray pump-probe experiments at the SLS[J]. Synchrotron Radiation News, 20, 35-39(2007).

[10] Zholents A A, Zolotorev M S. Femtosecond X-ray pulses of synchrotron radiation[J]. Physical Review Letters, 76, 912-915(1996).

[11] Billardon M, Elleaume P, Ortega J M, et al. First operation of a storage-ring free-electron laser[J]. Physical Review Letters, 51, 1652-1655(1983).

[12] Girard B, Lapierre Y, Ortega J M, et al. Optical frequency multiplication by an optical klystron[J]. Physical Review Letters, 53, 2405-2408(1984).

[13] Couprie M E, Billardon M, Velghe M, et al. Free-electron-laser oscillation on the super-ACO storage ring at Orsay[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 296, 13-19(1990).

[14] Couprie M E, Velghe M, Prazeres R, et al. Results and analysis of free-electron-laser oscillation in a high-energy storage ring[J]. Physical Review A, 44, 1301-1315(1991).

[15] Yamada K, Yamazaki T, Sugiyama S, et al. Visible oscillation of storage-ring free electron laser on TERAS[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 318, IN1,33-37(1992).

[16] Litvinenko V N, Burnham B, Emamian M, et al. Gamma-ray production in a storage ring free-electron laser[J]. Physical Review Letters, 78, 4569-4572(1997).

[17] Yamazaki T, Yamada K, Sugiyama S, et al. First lasing of the NIJI-IV storage-ring free-electron laser[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 331, 27-33(1993).

[18] Deacon D A G, Billardon M, Elleaume P, et al. Optical klystron experiments for the ACO storage ring free electron laser[J]. Applied Physics B, 34, 207-219(1984).

[19] Litvinenko V N, Park S H, Pinayev I V, et al. Operation of the OK-4/Duke storage ring FEL below 200 nm[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 475, 195-204(2001).

[20] Wu Y K, Vinokurov N A, Mikhailov S, et al. High-gain lasing and polarization switch with a distributed optical-klystron free-electron laser[J]. Physical Review Letters, 96, 224801(2006).

[21] Yamanaka C. Free electron laser: technical issues and prospects in Japan[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 331, 191-198(1993).

[22] Khan S, Bakr M, Höner M, et al. Coherent harmonic generation at DELTA: a new facility for ultrashort pulses in the VUV and THz regime[J]. Synchrotron Radiation News, 24, 18-23(2011).

[23] Chen Nian, Xu Hongliang, Liu Jinying, . Working condition of reconstructed optical klystron of CHG-SRFEL[J]. High Power Laser and Particle Beams, 15, 524-528(2003).

[24] Yu Lihua. Generation of intense UV radiation by subharmonically seeded single-pass free-electron lasers[J]. Physical Review A, 44, 5178-5193(1991).

[25] Stupakov G. Using the beam-echo effect for generation of short-wavelength radiation[J]. Physical Review Letters, 102, 074801(2009).

[26] Xiang Dao, Stupakov G. Echo-enabled harmonic generation free electron laser[J]. Physical Review Special Topics—Accelerators and Beams, 12, 030702(2009).

[27] Xiang Dao, Wan Weishi. Generating ultrashort coherent soft X-ray radiation in storage rings using angular-modulated electron beams[J]. Physical Review Letters, 104, 084803(2010).

[28] Stupakov G. Frequency multiplication using coherent radiation of a ‘‘snake’’ beam[J]. Physical Review Accelerators and Beams, 16, 010702(2013).

[29] Evain C, Loulergue A, Nadji A, et al. Soft X-ray femtosecond coherent undulator radiation in a storage ring[J]. New Journal of Physics, 14, 023003(2012).

[30] Deng Haixiao, Feng Chao. Using off-resonance laser modulation for beam-energy-spread cooling in generation of short-wavelength radiation[J]. Physical Review Letters, 111, 084801(2013).

[31] Feng Chao, Deng Haixiao, Wang Dong, et al. Phase-merging enhanced harmonic generation free-electron laser[J]. New Journal of Physics, 16, 043021(2014).

[32] Feng Chao, Zhao Zhentang. A storage ring based free-electron laser for generating ultrashort coherent EUV and X-ray radiation[J]. Scientific Reports, 7, 4724(2017).

[33] Wang Xiaofan, Feng Chao, Liu Tao, et al. Angular dispersion enhanced prebunch for seeding ultrashort and coherent EUV and soft X-ray free-electron laser in storage rings[J]. Journal of Synchrotron Radiation, 26, 677-684(2019).

[34] Li Changliang, Feng Chao, Jiang Bocheng. Extremely bright coherent synchrotron radiation production in a diffraction-limited storage ring using an angular dispersion-induced microbunching scheme[J]. Physical Review Accelerators and Beams, 23, 110701(2020).

[35] Li Changliang, Jiang Bocheng, Feng Chao, et al. Lattice design for angular dispersion enhanced microbunching in storage rings[J]. Journal of Instrumentation, 16, P03004(2021).

[36] Liu Weihang, Zhou Guanqun, Jiao Yi. Generating femtosecond coherent X-ray pulses in a diffraction-limited storage ring with the echo-enabled harmonic generation scheme[J]. Nuclear Science and Techniques, 29, 143(2018).

[37] Liu Weihang, Wu Yi, Jiao Yi, et al. Generation of two-color polarization-adjustable radiation pulses for storage ring light source[J]. Nuclear Science and Techniques, 30, 66(2019).

[38] Hwang J G, Schiwietz G, Abo-Bakr M, et al. Generation of intense and coherent sub-femtosecond X-ray pulses in electron storage rings[J]. Scientific Reports, 10, 10093(2020).

[39] Huang Nanshun, Deng Haixiao, Liu Bo, et al. Features and futures of X-ray free-electron lasers[J]. The Innovation, 2, 100097(2021).

[40] Agapov I. Feasibility of a ring FEL at low emittance storage rings[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 793, 35-40(2015).

[41] Kim K J, Shvyd’ko Y, Reiche S. A proposal for an X-ray free-electron laser oscillator with an energy-recovery linac[J]. Physical Review Letters, 100, 244802(2008).

[42] Huang Zhirong, Ding Yuantao, Schroeder C B. Compact X-ray free-electron laser from a laser-plasma accelerator using a transverse-gradient undulator[J]. Physical Review Letters, 109, 204801(2012).

[43] Lindberg R, Kim K J, Cai Y, et al. Transverse gradient undulats f a stage ring Xray FEL oscillat[C]Proceedings of FEL 2013. New Yk, NY, USA, 2013: 740748.

[44] Agapov I, Chae Y C, Hillert W. Low gain FEL oscillat option f PETRA IV[C]Proceedings of the 9th International Particle Accelerat Conference. Vancouver, BC, Canada: JACoW Publishing, 2018: 14201422.

[45] Cai Yunhai, Ding Yuantao, Hettel R, et al. An X-ray free electron laser driven by an ultimate storage ring[J]. Synchrotron Radiation News, 26, 39-41(2013).

[46] Di Mitr S. One way only to synchrotron light sources upgrade?[J]. Journal of Synchrotron Radiation, 25, 1323-1334(2018).

[47] Di Mitri S, Cornacchia M, Diviacco B, et al. Bridging the gap of storage ring light sources and linac-driven free-electron lasers[J]. Physical Review Accelerators and Beams, 24, 060702(2021).

[48] Li Changliang, Feng Chao, Jiang Bocheng, et al. Lattice design f the reversible SSMB[C]Proceedings of the 10th International Particle Accelerat Conference. Melbourne, Australia: JACoW Publishing, 2019: 15071509.

[49] KEK. KEK rept 20204[R].

[50] Jiang Bocheng, Feng Chao, Li Changliang, et al. A synchrotron-based kilowatt-level radiation source for EUV lithography[J]. Scientific Reports, 12, 3325(2022).

[51] Ratner D F, Chao A W. Steady-state microbunching in a storage ring for generating coherent radiation[J]. Physical Review Letters, 105, 154801(2010).

[52] Deng X J, Chao A W, Feikes J, et al. Single-particle dynamics of microbunching[J]. Physical Review Accelerators and Beams, 23, 044002(2020).

[53] Deng X J, Chao A W, Huang W H, et al. Courant-Snyder formalism of longitudinal dynamics[J]. Physical Review Accelerators and Beams, 24, 094001(2021).

[54] Deng X J, Huang W H, Li Z Z, et al. Harmonic generation and bunch compression based on transverse-longitudinal coupling[J]. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 1019, 165859(2021).

[55] Tang Chuanxiang, Deng Xiujie, Huang Wenhui, et al. An overview of the progress on SSMB[C]Proceedings of the 60th ICFA Advanced Beam Dynamics Wkshop on Future Light Sources. Shanghai, China: JACoW Publishing, 2018: 166170.

[56] Zhang Y, Deng X J, Pan Z L, et al. Ultralow longitudinal emittance storage rings[J]. Physical Review Accelerators and Beams, 24, 090701(2021).

[57] Deng Xiujie, Chao A, Feikes J, et al. Experimental demonstration of the mechanism of steady-state microbunching[J]. Nature, 590, 576-579(2021).