Personal profile
Personal profile
Title: Associate Professor
Contact number:
Department: Optical Physics
E-mail: songxinbing@bit.edu.cn
Mailing Address:
Contact number:
Department: Optical Physics
E-mail: songxinbing@bit.edu.cn
Mailing Address:
Research Interests
(1) Quantum imaging;
(2) Vortex beam;
(3) multi-photon quantum states;
(4) Wave front modulation.
(2) Vortex beam;
(3) multi-photon quantum states;
(4) Wave front modulation.
Education
2007-2012 Ph. D., Department of Physics, Beijing Normal University
2003-2007 Bachelor of Physics, Shandong Normal University
2003-2007 Bachelor of Physics, Shandong Normal University
Professional Experience
2021-present Associate Professor, School of Physics, Beijing Institute of Technology
2012-2021 Lecturer, School of Physics, Beijing Institute of Technology
2012-2021 Lecturer, School of Physics, Beijing Institute of Technology
Research Achievement
The research mainly focuses on correlation imaging and interference, beam modulation, multi-photon quantum states, etc., and some innovative achievements have been achieved:
(1) The second order correlation Talbot effect was experimentally observed by using thermal and entangled light sources, which corrected some misconceptions in quantum imaging research in the past;
(2) The non-localized dark field ghost imaging is realized by using the thermal light source, and the correlation imaging of strong light transmission objects and pure phase objects is realized;
(3) The complementary principle of particle property and wave of classical light is studied by second-order correlation.
(4) The entangled coherent state is constructed by using the compressed vacuum state and the coherent state.
He has published more than 30 papers, including PRL, PRA, APL, etc., representative papers:
[1] Xin-Bing Song, Jun Xiong, Xiangdong Zhang, and Kaige Wang*, Second-order Talbot self-imaging with pseudothermal light, Phys. Rev. A 82, 033823 (2010).
[2] Xin-Bing Song, Hai-Bo Wang, Jun Xiong, Kaige Wang, Xiangdong Zhang*, Kai-Hong Luo, and Ling-An Wu, Experimental Observation of Quantum Talbot Effects, Phys. Rev. Lett. 107, 033902 (2011).
[3] Xin-Bing Song, De-Qin Xu, Hai-Bo Wang, Jun Xiong, Xiangdong Zhang, De-Zhong Cao, and Kaige Wang*, Experimental observation of one-dimensional quantum holographic imaging, Appl. Phys. Lett. 103, 131111 (2013).
[4] Xinbing Song, Yifan Sun, Pengyun Li, Hongwei Qin, & Xiangdong Zhang, Bell’s measure and implementing quantum Fourier transform with orbital angular momentum of classical light, Sci. Rep. 5, 14113 (2015).
[5] De-Qin Xu, Xin-Bing Song, Hong-Guo Li, De-Jian Zhang, Hai-Bo Wang, Jun Xiong*, and Kaige Wang*, Experimental observation of sub-Rayleigh quantum imaging with a two-photon entangled source, Appl. Phys. Lett. 106, 171104 (2015).
[6] Yifan Sun, Xinbing Song, Hongwei Qin, Xiong Zhang, Zhenwei Yang, & Xiangdong Zhang*, Non-local classical optical correlation and implementing analogy of quantum teleportation, Sci. Rep. 5, 9175 (2015).
[7] Qiang Zeng, Tao Li, Xinbing Song*, and Xiangdong Zhang, Realization of optimized quantum controlled logic gate based on the orbital angular momentum of light, Opt. Express 24, 8186 (2016).
[8] Xin-Bing Song, Shi-Yao Fu, Xiong Zhang, Zhen-Wei Yang, Qiang Zeng, Chunqing Gao & Xiangdong Zhang*, Multimode quantum states with single photons carrying orbital angular momentum, Sci. Rep. 7, 3601 (2017).
[9] Anat Daniel*, Xin Bing Song, Dan Oron, and Yaron Silberberg, Mode conversion via wavefront shaping, Opt. Express 26, 22208 (2018).
[10] Ling-Yu Dou, Yaron Silberberg, and Xin-Bing Song*, Demonstration of complementarity between path information and interference with thermal light, Phys. Rev. A 99, 013825 (2019).
[11] Yonatan Israel, Lior Cohen, Xin-Bing Song, Jaewoo Joo, Hagai S. Eisenberg, and Yaron Silberberg, Entangled coherent states created by mixing squeezed vacuum and coherent light, Optica, 6, 753 (2019).
[12] Ling-Yu Dou, De-Zhong Cao, Lu Gao, and Xin-Bing Song*, Dark-field ghost imaging, Opt. Express 28, 37167 (2020).
[13] Ling‑Yu Dou, De‑Zhong Cao, De‑Qin Xu, An‑Ning Zhang, & Xin‑Bing Song*, Observation of positive–negative sub‑wavelength interference without intensity correlation calculation, Sci. Rep. 11, 2477 (2021).
[14] Ling-Yu Dou, Li-Qing Ren, De-Zhong Cao, and Xin-Bing Song*, Positive-negative ghost imaging with statistics of realizations, Phys. Rev. Appl. 16, 044013 (2021).
Sponsor Fund:
National Natural Science Foundation of China Youth Project, 11304016, Application of Interferometers in second-order correlation, 2014.01-2016.12.
(1) The second order correlation Talbot effect was experimentally observed by using thermal and entangled light sources, which corrected some misconceptions in quantum imaging research in the past;
(2) The non-localized dark field ghost imaging is realized by using the thermal light source, and the correlation imaging of strong light transmission objects and pure phase objects is realized;
(3) The complementary principle of particle property and wave of classical light is studied by second-order correlation.
(4) The entangled coherent state is constructed by using the compressed vacuum state and the coherent state.
He has published more than 30 papers, including PRL, PRA, APL, etc., representative papers:
[1] Xin-Bing Song, Jun Xiong, Xiangdong Zhang, and Kaige Wang*, Second-order Talbot self-imaging with pseudothermal light, Phys. Rev. A 82, 033823 (2010).
[2] Xin-Bing Song, Hai-Bo Wang, Jun Xiong, Kaige Wang, Xiangdong Zhang*, Kai-Hong Luo, and Ling-An Wu, Experimental Observation of Quantum Talbot Effects, Phys. Rev. Lett. 107, 033902 (2011).
[3] Xin-Bing Song, De-Qin Xu, Hai-Bo Wang, Jun Xiong, Xiangdong Zhang, De-Zhong Cao, and Kaige Wang*, Experimental observation of one-dimensional quantum holographic imaging, Appl. Phys. Lett. 103, 131111 (2013).
[4] Xinbing Song, Yifan Sun, Pengyun Li, Hongwei Qin, & Xiangdong Zhang, Bell’s measure and implementing quantum Fourier transform with orbital angular momentum of classical light, Sci. Rep. 5, 14113 (2015).
[5] De-Qin Xu, Xin-Bing Song, Hong-Guo Li, De-Jian Zhang, Hai-Bo Wang, Jun Xiong*, and Kaige Wang*, Experimental observation of sub-Rayleigh quantum imaging with a two-photon entangled source, Appl. Phys. Lett. 106, 171104 (2015).
[6] Yifan Sun, Xinbing Song, Hongwei Qin, Xiong Zhang, Zhenwei Yang, & Xiangdong Zhang*, Non-local classical optical correlation and implementing analogy of quantum teleportation, Sci. Rep. 5, 9175 (2015).
[7] Qiang Zeng, Tao Li, Xinbing Song*, and Xiangdong Zhang, Realization of optimized quantum controlled logic gate based on the orbital angular momentum of light, Opt. Express 24, 8186 (2016).
[8] Xin-Bing Song, Shi-Yao Fu, Xiong Zhang, Zhen-Wei Yang, Qiang Zeng, Chunqing Gao & Xiangdong Zhang*, Multimode quantum states with single photons carrying orbital angular momentum, Sci. Rep. 7, 3601 (2017).
[9] Anat Daniel*, Xin Bing Song, Dan Oron, and Yaron Silberberg, Mode conversion via wavefront shaping, Opt. Express 26, 22208 (2018).
[10] Ling-Yu Dou, Yaron Silberberg, and Xin-Bing Song*, Demonstration of complementarity between path information and interference with thermal light, Phys. Rev. A 99, 013825 (2019).
[11] Yonatan Israel, Lior Cohen, Xin-Bing Song, Jaewoo Joo, Hagai S. Eisenberg, and Yaron Silberberg, Entangled coherent states created by mixing squeezed vacuum and coherent light, Optica, 6, 753 (2019).
[12] Ling-Yu Dou, De-Zhong Cao, Lu Gao, and Xin-Bing Song*, Dark-field ghost imaging, Opt. Express 28, 37167 (2020).
[13] Ling‑Yu Dou, De‑Zhong Cao, De‑Qin Xu, An‑Ning Zhang, & Xin‑Bing Song*, Observation of positive–negative sub‑wavelength interference without intensity correlation calculation, Sci. Rep. 11, 2477 (2021).
[14] Ling-Yu Dou, Li-Qing Ren, De-Zhong Cao, and Xin-Bing Song*, Positive-negative ghost imaging with statistics of realizations, Phys. Rev. Appl. 16, 044013 (2021).
Sponsor Fund:
National Natural Science Foundation of China Youth Project, 11304016, Application of Interferometers in second-order correlation, 2014.01-2016.12.
Fingerprint
Dive into the research topics where Xinbing Song is active. These topic labels come from the works of this person. Together they form a unique fingerprint.
- 1 Similar Profiles
-
High-performance photomultiplication-type quantum dot IR photodetectors at low applied voltages
Bai, H., Yang, S., Ge, Z., Liu, M., Hong, M., Pang, R., Song, X., Jiang, Y., Zou, B. & Tang, L., 18 Sept 2025, In: Journal of Materials Chemistry C. 13, 36, p. 19055-19064 10 p.Research output: Contribution to journal › Article › peer-review
1 Link opens in a new tab Citation (Scopus) -
Superluminal Spacetime Boundary, Time Reflection and Quantum Light Generation From Relativistic Plasma Mirrors
Pan, C., Song, X., Cao, Y., Xiong, L., Lan, X., Wang, S., Leng, Y. & Pan, Y., 19 Nov 2025, In: Laser and Photonics Reviews. 19, 22, e01986.Research output: Contribution to journal › Article › peer-review
-
Bio-Inspired Synthesis of Square-Shaped Anhydrous Hypoxanthine Nanoplatelet Crystals with Superior Optical Properties
Hou, X., Ren, Y., Zhang, Y., Hao, J., Wang, Y., Song, X., Gao, J. & Ma, Y., 5 Jun 2024, In: Crystal Growth and Design. 24, 11, p. 4481-4492 12 p.Research output: Contribution to journal › Article › peer-review
3 Link opens in a new tab Citations (Scopus) -
Biomimetic synthesis of single-crystalline anhydrous xanthine nanoplates in an aqueous solution with high reflectivity
Hou, X., Wang, Y., Song, X., Gao, J. & Ma, Y., 6 May 2024, In: Soft Matter. 20, 22, p. 4422-4433 12 p.Research output: Contribution to journal › Article › peer-review
2 Link opens in a new tab Citations (Scopus) -
In vitro crystallization of single crystalline guanine microplates mediated by proteins extracted from carp fish Cyprinus carpio
Ren, Y., Hou, X., Zhang, Y., Hao, J. Y., Gao, J., Song, X. & Ma, Y., 6 May 2024, In: CrystEngComm. 26, 23, p. 3033-3043 11 p.Research output: Contribution to journal › Article › peer-review
1 Link opens in a new tab Citation (Scopus)