1. Lu-Xin Xu, Shun-Cai Zhao*, Sheng-Nan Zhu, and Lin-Jie Chen. Differentiation of correlated fluctuations in site energy on excitation energy transfer in photosynthetic light-harvesting complexes. Results in Physics, 38 (7): 105597, 2022.

2. Sheng-Qiang Zhong; Shun-Cai Zhao*; Sheng-Nan Zhu. Photovoltaic performances in a cavity-coupled double quantum dots photocell. Results in Physics, 27(7):104503, 2021.

3. Sheng-Qiang Zhong; Shun-Cai Zhao*; Sheng-Nan Zhu. Photovoltaic properties enhanced by the tunneling effect in a coupled quantum dot photocell. Results in Physics, 24(4): 104094, 2021.

4.Shun-Cai Zhao*; Jing-Yi Chen; Xin Li. Different roles of quantum interference in a quantum dot photocell with two intermediate bands. Eur. Phys. J. Plus, 135(892): 1-10, 2020.

5.Jing-Yi Chen; Shun-Cai Zhao* Radiative recombination rate suppressed in a quantum photocell with three electron donors. Eur. Phys. J. Plus, 135(92): 1-8, 2020.

6.Shun-Cai Zhao*; Xin Li. Monochromatic Composite Right/Left Handedness in the Quantized Composite Right/Left Handed Transmission Line. Annalen der Physik, 531(12): 1900495, 2019.

7.Shun-Cai Zhao*; Jing-Yi Chen. Enhanced quantum yields and efficiency in a quantum dot photocell modeled by a multi-level system. New Journal of Physics, 21(6): 103015, 2019.

8.Shun-Cai Zhao*; Qi-Xuan Wu. High quantum yields generated by a multi-band quantum dot photocell. Superlattices and Microstructures, 137(3): 106329, 2019.

9.Shun-Cai Zhao*; Hong-Wei Guo; Xiao-Jing Wei. The manipulated left-handedness in a rare-earth-ion-doped optical fiber by the incoherent pumping field. Optics Communications, 400: 30-33, 2017.

10.Shun-Cai Zhao*; et.al. Negative Refraction with Little Loss Manipulated by the Voltage and Pulsed Laser in Double Quantum Dots. Prog. Theor. Phys., 128(2): 243-250, 2012.

11.Shun-Cai Zhao*, Negative refraction with absorption suppressed by EIT in a left-handed atomic system. Science China, 55(2): 213-218, 2012.

12.Shun-Cai Zhao*; Zheng-Dong Liu*; Qi-Xuan Wu. Zero absorption and a large negative refractive index in a left-handed four-level atomic medium. Journal of Physics B, 43(4): 455051-455057, 2010.

13. Shun-Cai Zhao*, Xin Li, Ping Yang, and Qi-Xuan Wu. Dual peaks evolving into a single-peak for subwavelength 2-D atom localization in a V-type atomic system. Chinese Journal of Physics, 55:1055–1061, 2017.

14. Xiao-Jing Wei and Shun-Cai Zhao*. Left-handedness in the balanced/unbalanced resonance conditions of a quantized composite right-left handed transmission line. Eur. Phys. J. B, 93(81):1–6, 2020.

15. Shun-Cai Zhao*; Hong-Wei Guo; Xiao-Jing Wei，Negative refraction index of the mesoscopic left-handed transmission line in the thermal Fock state. Optical and Quantum Electronics, 49(6): 222, 2017.

16. Ling-Fang Li; Shun-Cai Zhao*. Influence of the coupled-dipoles on photosynthetic performance in a photosynthetic quantum heat engine. Chin. Phys. B, 30(4): 044215, 2021.

17. Shun-Cai Zhao*; Xin Li; Ping Yang. Localization of cold Rb-87 atom simulated by a three-level quantum system within half-wavelength domain. Superlattices and Microstructures, 106(4): 184-188, 2017.

[18] X. Li, Y. Xu, S. C. Zhao, and X. Yang. Driving suppresses decoherence: from a single two-level system to a composite system. Eur. Phys. J. D, 73(2):25, 2019. 

[19] Q. X. Wu and S. C. Zhao∗ . Wider frequency domain for negative refraction index in a quantized composite2 right-left handed transmission line. Chin. Phys. B, 27(6):68102, 2018. 

[20] X. J. Wei, S. C. Zhao∗ , and H. W. Guo. The thermal effffect on the left-handedness of the mesoscopic composite right-left handed transmission line. Superlattices & Microstructures, 110:313, 2017. 

[21] S. C. Zhao∗ , H. W. Guo, and X. J. Wei. The manipulated left-handedness in a rare-earth-ion-doped optical fifiber by the incoherent pumping fifield. Optics Communications, 400:30–33, 2017.

[22] S. C. Zhao∗ , X. Li, P. Yang, and Q. X. Wu. Dual peaks evolving into a single-peak for sub-wavelength 2-D atom localization in a V-type atomic system. Chin. J Phys., 55:1055–1061, 2017. 

[23] S. C. Zhao∗ , X. Li, and P. Yang. Localization of cold Rb-87 atom simulated by a three-level quantum system within half-wavelength domain. Superlattices & Microstructures, 6:184–188, 2017. 

[24] S. C. Zhao∗ , H. W. Guo, and X. J. Wei. Negative refraction index of the mesoscopic left-handed transmission line in the thermal fock state. Optical & Quantum Electronics, 49(6), 2017.

[25] S. C. Zhao∗ , X. J. Wei, and Q. X. Wu. Negative refraction index of the quantum lossy left-handed transmission lines affffected by the displaced squeezed fock state and dissipation. Superlattices & Microstructures, 105:209–215, 2017. 

[26] H. W. Guo, S. C. Zhao∗ , X. J. Wei, and X. Li. Negative refraction index manipulated by a displaced squeezed fock state in the mesoscopic dissipative left-handed transmission line. Chin. Phys. Lett., (3):31–34, 2017.

[27] H. W. Guo, S. C. Zhao∗ , X. J. Wei, and J. Jia. Quantum effffects on negative refraction index of mesoscopic left-handed transmission line in thermal fock state. Acta Photonica Sinica (In Chinese), 46(4):419002, 2017. 

[28] S. C. Zhao∗ , Q. X. Wu, and K. Ma. Adjusting the left-handedness in a cold Rb-87 atomic system via multiple parameter modulation. Chin. Phys. Lett., (54):756–760, 2016.

[29] S. C. Zhao∗ and Q. X. Wu. Three-level ∧ -type atomic system localized by the parameters of the two orthogonal standing-wave fifields. Journal of Applied Mathematics and Physics, (4):1455–1462, 2016.

[30] Y. Y. Xu, J. Liu, and S. C. Zhao. Comparing two defifinitions of work for a biological quantum heat engine. Comunications in Theoretical Physics, (64):409–414, 2015. 

[31] S. Y. Zhang, A. L. Gong, and S. C. Zhao∗ . 2D isotropic negative permeability in a -type three-level atomic system. Canadian Journal of Physics, 93(6):641–645, 2015. 

[32] S. C. Zhao∗ , S. Y. Zhang, Q. X. Wu, and J. Jia. Left-handedness with three zero-absorption windows tuned by the incoherent pumping fifield and inter-dot tunnelings in a gaas/algaas triple quantum dots system. Chin. Phys. Lett., 32(5):058104, 2015. 

[33] S. C. Zhao∗ , Q. X. Wu, and K. Ma. 2-D isotropic negative refractive index in a N-type four-level atomic system. Open Physics, 13(1), 2015. 

[34] S. Y. Zhang, A. L. Gong, and S. C. Zhao∗ . Electromagnetically induced isotropic 2D left-handedness in a v-type three-level atomic system. Acta Sinica Quantum Optica, 21(2):123, 2015.

[35] S. C. Zhao∗ , S. Y. Zhang, and Y. Y. Xu. Large and tunable negative refractive index via electromagnetically induced chirality in a semiconductor quantum well nanostructure. JETP Lett., 100(6):385–389, 2014.

[36] S. C. Zhao∗ , Q. X. Wu, and A. L. Gong. Effffect of spontaneously generated coherence and detuning on 2d atom localization in two orthogonal standing-wave fifields. Chin. Phys. Lett., 31(3):034206, 2014. 

[37] S. C. Zhao∗ , Q. X. Wu, and A. L. Gong. Algebraic analysis of electromagnetic chirality-induced negative refractive index in a four-level atomic system. Eur. Phys. J. D, 67(2):28 (6 pp.), 2013. 

[38] S. C. Zhao∗ , X. F. Qian, Y. P. Zhang, and Y. A. Zhang. Negative refraction with little loss manipulated by the voltage and pulsed laser in double quantum dots. Progress of Theoretical Physics, 128(2):243–250, 2012. 

[39] S. C. Zhao∗ . Negative refraction with absorption suppressed by electromagnetically induced transparency3 in a left-handed atomic system. Science China Physics,Mechanics & Astronomy, 55(2):213–218, 2012.

[40] S. C. Zhao∗ , Z. D. Liu, J. Zheng, G. Li, and N. Liu. Negative refraction with low absorption using eit in a four-level left-handed atomic system. Optik, 123(12):1063–1066, 2012. 

[41] S. C. Zhao∗ . Effffect of spontaneously generated coherence on left-handedness in a degeneracy atomic system. JETP Lett., 94(5):347–352, 2011. 

[42] S. C. Zhao∗ , Z. D. Liu, J. Zheng, and G. Li. Electromagnetic chirality-induced negative refraction with the same amplitude and anti-phase of the two chirality coeffiffifficients. Chin. Phys. B, 20(6):067802, 2011.

[43] Z. Q. Zhang, Z. D. Liu, S. C. Zhao, J. Zheng, Y. F. Ji, and N. Liu. Negative refractive index in a four-level atomic system. Chin. Phys. B, 23(12):244–248, 2011. 

[44] S. C. Zhao∗ , Z. D. Liu, and Q. X. Wu. Negative refraction without absorption via both coherent and incoherent fifields in a four-level left-handed atomic system. Optics Communications, 283(17):3301–3304, 2010. 

[45] Z. Q. Zhang, Z. D. Liu, S. C. Zhao, and J. Zheng. Electromagnetically induced left handedness in a v-type four-level atomic system. Chin. Opt. Lett., 8(12):1187–1190, 2010. 

[46] S. C. Zhao∗ , Z. D. Liu, and Q. X. Wu. Zero absorption and a large negative refractive index in a left-handed four-level atomic medium. J Phys. B, 43(4):045505, 2010. [47] J. Zheng, Z. D. Liu, and S. C. Zhao. Impact of controlling fifields on the absorption-dispersion properties in an M-type atomic system. Journal of Nanchang University(Natural Science) , 39(4):728–733, 2010. 

[48] S. C. Zhao∗ , Z. D. Liu, and Q. X. Wu. Left-handedness without absorption in the four-level Y-type atomic medium. Chin. Phys. B, 19(1):350–354, 2010. 

[49] S. C. Zhao∗ and Z. D. Liu. Left-handness in a four-level atomic system. International Journal of Quantum Information, 7(4):747–754, 2009. 

[50] S. C. Zhao∗ and Z. D. Liu. Manipulative properties of asymmetric double quantum dots via laser and gate voltage. Chin. Phys. Lett., 26(7):077802, 2009.4