Faculty Profile
 
  Bao-Sen Shi
     
Department: Department of Optics & Optical Engineering
Mailing Address:
Department of Optics & Optical Engineering, University of Science and Technology of China, 96 Jinzhai Rd, Hefei, Anhui, PR China
Postal Code:
230026
Phone:
+86-551-63600641
Fax:
0551-63606828
Homepage:
http://www.quantumdrshi.com/
 
       

Research Profile

	  
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Selected Publications
1)  Highly efficient storage of 25-dimensional photonic qudit in a cold-atom-based quantum memory , Phys. Rev. Lett. , 202312 , 131, 240801
2) Indirect precise angular control using four-wave mixing , Appl. Phys. Lett. , 2014 , 104,171103
3) Generation of light with controllable spatial patterns via the sum frequency in quasi-phase matching crystals , Science Report , 2014 , 4, 5650
4) Optical vortex beam based optical fan for high-precision optical measurements and optical switching , Opt.Lett. , 2014 , 39, 5098
5) Orbital angular momentum light frequency conversion and interference with quasi-phase matching crystals , Opt. express , 2014 , 22,020298
6) Image Cloning beyond diffraction based on coherent population trapping in a hot Rubidium vapor , Opt. Lett. , 2014 , 39,240
7) Cavity-enhanced bright photon pairs at telecom wavelengths with a triple-resonance configuration , J.O.S.A.-B , 2014 , 31,128
8) Light storage based on four-wave mixing and electromagnetically induced transparency in cold atoms , Phys. Rev. A , 2013 , 87,013845
9) Multimode image memory based on a cold atomic ensemble , Phys. Rev. A , 2013 , 897, 045806
10) Multiple image storage and frequency conversion in a cold atomic ensemble , Phys. Rev. A , 2013 , 87, 053830
11) Single-photon-level quantum image memory based on cold atomic ensembles , Nat. Commun. , 2013 , 4, 2527
12) Experimental up-conversion of images. , PHYSICAL REVIEW A , 2012 , 86, 033803
13) Generation of non-classical correlated photon pairs via a ladder-type atomic configuration: theory and experiment , Opt. Express , 2012 , Vol. 20, No. 10 ,p11433-11444
14) Linear up-conversion of orbital angular momentum , Opt. Lett. , 2012 , 37,3270
15) Nonlocal linear compression of two-photon time-interval distribution , Phys. Rev. A , 2013 , 88,061802
16) Protecting single-photon entangled state from photon loss with noiseless linear amplification , Phys. Rev. A , 2012 , 86,034302
17) Image transfer through two sequential four-wave-mixing processes in hot atomic vapor , Phys. Rev. A. , 2012 , 85, 053815 (2012)
18) Observation of Anomalous Orbital Angular Momentum Transfer in Parametric Nonlinearity , Phys. Rev. Lett. , , 130, 153803
19)  Conformal frequency conversion for arbitrary vectorial structured light , Optica , 2022 , 9,187
20) Non-classical Correlated Photon Pairs Generation via Cascade Transition of 5S1/2-5P3/2-5D5/2 in a Hot 85Rb Atomic Vapor , Chin. Phys. Lett. , 2014 , 31,064208
21) Fast generation of many-atom maximal entanglement in spin-1 Bose-Einstein condensates , Phys.Rev. A , 2012 , 85, 035601 (2012)
22) Enhanced metrology at the critical point of a many-body Rydberg atomic system , Nat. Phys. , 2022 , 18,1447
23) Characterizing dispersion and absorption parameters of metamaterial using entangled photons , Phys. Rev. A. , 2012 , 85, 023841 (2012)
24) Deep learning enhanced Rydberg multifrequency microwave recognition , Nat. Commn. , 2022 , 13,1997
25) Properties of a dielectric plate using entangled two-photon states , Chin. Phys. B , 2012年 , 21,094204
26) Modulating an image through a non-material lens in a vapor cell , Opt. Commun. , 2012 , 285 (2012) 1954–1958
27) Harmonics-assisted optical phase amplifier , Light: Sci. & Appl. , 2022 , 11,312
28) Two-Photon Atomic Coherence Effect of Transition 5..1/2.5..3/2.4..5/2(4..3/2) of 85Rb atoms , Chin.Phys.Lett. , 2012 , Vol. 29, No. 2 (2012) 024202
29) Long-lived memory for orbital angular momentum quantum states , Phys. Rev. Lett. , 2022 , 129,193601
30) Realization of a Two-Dimensional Magneto-optical Trap with a High Optical Depth , Chin。 Phys。 Lett。 , (2012) , Vol. 29, No. 2 (2012) 024205
31) All-optical reversible single-photon isolation at room temperature , Sci.Adv. , 2021 , 7: eabe8924
32) Adjusting the properties of the photon generated via Optical parametric oscillator by pulse pumped laser , Chin. Phys. B , 2011 , 20, 114206
33) Angular-spectrum-dependent interference , Light: Sci. & Appl. , 2021 , 10,217
34) Spectrum Analysis of a Pulsed Photon Source Generated from Periodically Poled Lithium Niobate , Chin. Phys. Lett. , 2011 , 27, 074212
35) Phase diagram and self-organizing dynamics in a thermal ensemble of strongly-interacting Rydberg atoms , Phys. Rev. X , 2020 , 10,021023
36) Efficient Generation of CW Ultra-Violet Light with a Type-I Phase Matched Periodically-Poled KTP Crystal in a Ring Cavity , Horizons in World Physics. Volume 272 , 2012 , 2012
37) Four photons interfering but showing the two-photon interference behaviour , J. Mod. Opt. , 2006 , 53, 1003
38) Experimental demonstration of Einstein-Podolsky-Rosen entanglement in rotating coordinate space , Science Bulletin , 2020 , 65(4),280
39) Preparation of narrow-band photons for atomic-based quantum memory with a type-I phase matched periodical poled KTP crystal , Front. Phys. China. , 2010 , 5, 131-146 Review paper
40) Temporal Wheeler's delayed-Choice Experiment based on Cold Atomic Quantum Memory , NPJ Quantum Information , 2020 , 6,72
41) Generation of narrow-band photon pairs for quantum momery , Opt. Commun. , 2010 , 283,2974
42) Observation of time correlation function of multimode two-photon pairs on a rubidium D$_2$ line , Opt. Lett. , (2008) , 33, 2191
43) Metasurface enabled quantum edge detection , Sci.Adv. , 2020 , 16,EABC4385
44) Quantum interference of multimode two-photon pairs with a Michelson interferometer , Opt. Commun. , 2010 , 283,551
45) Control of light speed: From slow light to superluminal light , Phys. Rev. A. , (2008) , 78, 013804
46)  Revealing the Behavior of Photons in a Birefringent Interferometer , Phys. Rev. Lett. , 2018 , 120,263120
47) Experimental measuring the coherence length of the single photon generated via a degenerated optical parameteric oscillator far below threshold , J. Mod. Opt. , 2010 , 57, 330
48) An ultra-bright two-photon source with a type-I bulk periodically poled potassium titanyl phosphate , Optics Communications, , (2008) , 281, 3390-3394
49)  Quantum twisted double-slits experiments: confirming wavefunctions’ physical reality , Science Bulletin , 2017 , 62(17):1185-1192
50) Probabilistic and robust preparation of a GHZ-type state via atomic ensemble and linear optics , Chin. Phys. B , 2009 , 18,5133
51) Non-degenerate non-classical photon pairs in a hot atomic ensemble , Opt. Express. , (2008) , 16, 21708
52) Generation of a non-classical correlated photon pair via a spontaneous four-wave mixing in a cold atomic ensemble , Chin. Phys. Lett. , 2009 , 26,064204
53) Entanglement of the orbital angular momentum states of photons generated in a hot atomic ensemble , Phys. Rev. A. , (2008) , 78, 053810
54) Quantum secure direct communication with quantum memory , Phys. Rev. Lett. , 2017 , 118(22): 220501
55) Non-classical correlation between the single photon and the collective spin excited state of the cold atomic ensemble , Chin. Opt. Lett. , 2009 , 11,1048
56) Efficient generation of a photon pair in a bulk periodically poled potassium titanyl phosphate , Optics Communication , (2007) , 278, 363
57) Experimental realization of entanglement inmultiple degrees of freedom between two quantum memories , Nat. Commn. , 2016 , 7,13514
58) Efficient cw violet-light generation in a ring cavity with a periodically poled KTP , Optics Communications, , 2008 , 281, 4114-4117
59) Time uncertainty of a photon pair creation in a bulk periodically poled potassium titanyl phosphate pumped by a femtosecond laser , New J. Physics , (2006) , 8, 38
60) High-dimensionalentanglement between distant atomic-ensemble memories , Light: Sci. & Appl. , 2016 , 5, e16157
61) Two narrow bandwidth photons interfering in an electromagnetically induced transparency (EIT) system , CHINESE PHYSICS B, , 2008 , 17, 1798-180
62) Creation of a polarization W state using optical fibre multiports , J. Mod. Opt. , (2005) , 52,755
63) Orbital angular photonic quantum interface , Light: Sci. & Appl. , 2016 , 5, e16019
64) Photonic Realization of Quantum Information Systems , Topics in Applied Physics , 2006 , Springer出版社图书 Part IV 243-272
65) Experimental verification of fault tolerant quantum key distribution protocol , Optics Express , (2005) , 13, 9415
66) Orbital Angular Momentum-Entanglement Frequency Transducer , Phys. Rev. Lett. , 2016 , 117, 103601
67) Highly efficient generation of pulsed photon pairs with bulk periodically poled potassium titanyl phosphate , J.Opt.Soc.Am.-B , (2004) , 21, 2081
68) On-chip coherent conversion of photonicquantum entanglement between different degrees of freedom , Nat. Commn. , 2016 , 7, 11985
69) Observation of antinormally ordered Hanbury Brown-Twiss correlations , Phys.Rev.Lett. , (2004) , 92 113601
70) Raman quantum memory of photonic polarized entanglement , Nat. Photon. , 2015 , 9,332
71) Generation of a pulsed polarization entangled photon pair using a Sagnac interferometer , PHYSICAL REVIEW A , (2004) , 69. 013803
72) Hybrid-cascaded generation of tripartite telecom photons using an atomic ensemble and a nonlinear waveguide , Optica , 2015 , 2,642
73) Hypothesis testing for an entangled state produced by spontaneous parametric down-conversion , Phys. Rev. A , 2006 , 74,062321
74) Quantum Storage of Orbital Angular Momentum Entanglement in an Atomic Ensemble , Phys. Rev. Lett. , 2015 , 114.050502
75) Quantum entanglement swapping using spontaneous parametric down-conversion , Phys. Rev. A , 2004 , 69, 014301-1-4
76) Optical Precursor with Four-Wave Mixing and Storage Based on a Cold-Atom Ensemble , Phys. Rev. Lett. , 2015 , 114.093601
77) Preparation of a pulsed polarization entangled photon pair via interference , Opt. Commun. , 2004 , 235, 247-252
78) Single-photon-level quantum image memory based on cold atomic ensembles , Nat. Commn. , 2014 , 4,2527
79) Bichromatic field generation from double-four-wave mixing in a double-electromagnetically induced transparency system , New. J. Phys. , , 14,073047 (2012)
 
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