[1] LANDAU L D, BELL J S, KEARSLEY M J et al[M]. Electrodynamics of continuous media(2013).

[2] PENDRY J B. A chiral route to negative refraction[J]. Science, 306, 1353-1355(2004).

[3] KÄSTEL J, FLEISCHHAUER M, YELIN S F et al. Tunable negative refraction without absorption via electromagnetically induced chirality[J]. Physical Review Letters, 99, 073602(2007).

[4] FLEISCHHAUER M, IMAMOGLU A, MARANGOS J P. Electromagnetically induced transparency: optics in coherent media[J]. Reviews of Modern Physics, 77, 633-673(2005).

[5] BA Nuo, WANG Lei, WU Xiangyao et al. Tunable photonic bandgap based on electromagnetically induced transparency in one dimensional atomic lattices[J]. Acta Photonica Sinica, 44, 0627002(2015).

[6] BOLLER K J, IMAMOĞLU A, HARRIS S E. Observation of electromagnetically induced transparency[J]. Physical Review Letters, 66, 2593(1991).

[7] SHELBY R A, SMITH D R, SCHULTZ S. Experimental verification of a negative index of refraction[J]. Science, 292, 77-79(2001).

[8] KHAN L, BACHA B A, WAHID U et al. Birefringence of rotary photon drags through induced chiral atomic medium[J]. Physica Scripta, 95, 075109(2020).

[9] LEONHARDT U. Optical conformal mapping[J]. Science, 312, 1777-1780(2006).

[10] PENDRY J B, SCHURIG D, SMITH D R. Controlling electromagnetic fields[J]. Science, 312, 1780-1782(2006).

[11] XU Cuilian, MENG Yueyu, WANG Jiafu et al. Optically transparent hybrid metasurfaces for low infrared emission and wideband microwave absorption[J]. Acta Photonica Sinica, 50, 0416001(2021).

[12] MCCALL M W, FAVARO A, KINSLER P et al. A spacetime cloak, or a history editor[J]. Journal of Optics, 13, 024003(2010).

[13] LUKENS J M, LEAIRD D E, WEINER A M. A temporal cloak at telecommunication data rate[J]. Nature, 498, 205-208(2013).

[14] WU K, WANG G P. Design and demonstration of temporal cloaks with and without the time gap[J]. Optics Express, 21, 238-244(2013).

[15] ZHOU F, YAN S, ZHOU H et al. Field-programmable silicon temporal cloak[J]. Nature Communications, 10, 2726(2019).

[16] JABAR M S A, BACHA B A, AHMAD I. Temporal cloak via Doppler broadening[J]. Laser Physics, 25, 065405(2015).

[17] LI B, WANG X, KANG J et al. Extended temporal cloak based on the inverse temporal Talbot effect[J]. Optics Letters, 42, 767-770(2017).

[18] BACHA B A, GHAFOOR F, AHMAD I et al. Gain assisted multiple superluminal regions via a Kerr nonlinearity in a double lambda-type atomic configuration[J]. Laser Physics, 24, 055401(2014).

[19] BACHA B A, JABAR M S A. The event cloaking from a birefringent medium via Kerr nonlinearity[J]. Journal of Optics, 20, 095703(2018).

[20] AHMAD H, RAHMAN A U, WAHID U et al. Space-time cloaking through a chiral atomic medium[J]. Optical and Quantum Electronics, 53, 466(2021).

[21] ARIF S M, BACHA B A, ULLAH S S et al. Tunable control of internet of things information hacking by application of the induced chiral atomic medium[J]. Soft Computing, 26, 10643-10650(2022).

[22] CHREMMOS I. Temporal cloaking with accelerating wave packets[J]. Optics Letters, 39, 4611-4614(2014).

[23] KHAN H, HANEEF M. Birefringence in a chiral medium, via temporal cloaking[J]. Laser Physics, 27, 055201(2017).