近期论文
查看导师最新文章
(温馨提示:请注意重名现象,建议点开原文通过作者单位确认)
2019
[1]Yubing Han, Xiao Lu, Zhimin Zhang, Wenjie Liu, Yuchen Chen, Xu Liu, Xiang Hao, and Cuifang Kuang*, 'Ultra-fast, universal super-resolution radial fluctuations (SRRF) algorithm for live-cell super-resolution microscopy,' Opt. Express 27, 38337-38348 (2019).
[2]Yuchen Chen#, Shaocong Liu#, Chengfeng Zhang, Zhimin Zhang, Cuifang Kuang*, Xiang Hao, Xu Liu. Image scanning difference microscopy[J]. Journal of microscopy, 276(2), 98-106, 2019.
[3]Zhimin Zhang#, Shaocong Liu#, Liang Xu, Yubing Han, Cuifang Kuang*, Yong Liu*, Xiang Hao, Hongqin Yang and Xu Liu. Super-resolution microscopy based on parallel detection[J]. Journal of Innovative Optical Health Sciences. 12(06), 1950023, 2019.
[4]Minfei He#, Yubing Han#, Yanhong Gan, Zhimin Zhang, Wenjie Liu, Liang Xu, Cuifang Kuang*, Xiang Hao, Xu Liu. Dynamic live-cell super-resolution imaging with parallelized fluorescence emission difference microscopy. Optics Communications, 125087, 2019.
[5] Liu W, Kuang C*, Yuan Y, et al. Simultaneous Two-Angle Axial Ratiometry for Fast Live and Long-Term Three-Dimensional Super-Resolution Fluorescence Imaging[J]. The Journal of Physical Chemistry Letters, 2019, 10: 7811-7816.(cover paper)
[6]Yanhong Gan#, Minfei He#, Zhimin Zhang, Shaocong Liu, Liang Xu, Xiang Hao, Cuifang Kuang*, and Xu Liu, 'Label-free difference super-resolution microscopy based on parallel detection,' Appl. Opt. 58, 9069-9074 (2019)
[7] QiulanLiu#, YouhuaChen#, WenjieLiu, YubingHan, RuizhiCao, ZhiminZhang, CuifangKuang*, XuLiu. Total internal reflection fluorescence pattern-illuminated Fourier ptychographic microscopy[J]. Optics and Lasers in Engineering, 2019, 123: 45-52.
[8] Vannhu Le#, Xiaona Wang#, Cuifang Kuang*, Xu Liu. Resolution enhancement of confocal fluorescence microscopy via two illumination beams[J]. Optics and Lasers in Engineering, 2019, 122: 8-13.
[9] Diyi Liu, Yicheng Li, Anwar Hussain, Yinxu Bian, Cuifang Kuang*, Xu Liu. Probe separation and noise suppression in lensless microscopy[J]. Applied Physics B, 2019, 125(7): 118.
[10] Shiyi Sun, Minfei He, Zhimin Zhang, Wensheng Wang, Xin Yang, Cuifang Kuang*, and Xu Liu . Enhancing the axial resolution of two-photon imaging[J]. Applied Optics, 2019, 58(18): 4892-4897.
[11] Yubing Han, Meihua Li , Meng Zhang, Xiaoshuai Huang, Liangyi Chen, Xiang Hao, Cuifang Kuang, Xu Liu, Yuhui Zhang*. Cell‐permeable organic fluorescent probes for live‐cell super‐ esolution imaging of actin filaments[J]. Journal of Chemical Technology & Biotechnology, 2019, 94(6): 2040-2046.
[12] Yan Kuai#, Junxue Chen#, Xi Tang, Yifeng Xiang, Fengya Lu, Cuifang Kuang, Liang Xu, Weidong Shen, Junjie Cheng, Huaqiao Gui, Gang Zou, Pei Wang, Hai Ming, Jianguo Liu, Xu Liu, Joseph R. Lakowicz, Douguo Zhang*. Label-free surface-sensitive photonic microscopy with high spatial resolution using azimuthal rotation illumination[J]. Science advances, 2019, 5(3): eaav5335.
[13] Yong Liu, Xiaona Wang, Shaocong Liu, Cuifang Kuang*. Fluorescence emission difference microscopy by superoscillation excitation, Journal of Microscopy,274(3),132-138(2019). (cover paper)
[14] Wenjie Liu, Qiulan Liu, Zhimin Zhang, Yubing Han, Cuifang Kuang*, Liang Xu, Hongqin Yang, and Xu Liu. Three-dimensional super-resolution imaging of live whole cells using galvanometer-based structured illumination microscopy[J]. Optics express, 2019, 27(5): 7237-7248.
[15] XutaoMo, Tao Zhang*, Bin Wang, Xianshan Huang, Cuifang Kuang, Xu Liu, Alleviating image artifacts in wavefront coding extended depth of field imaging system, Optics Communications, 436, 232-238(2019).
[16] Anwar Hussain, Yicheng Li, Diyi Liu, Yinxu Bian, Cuifang Kuang, Xu Liu*, Axial scanning in lensless microscopy to achieve high resolution, Applied Physics B, 125:43(2019)
[17] Yinxu Bian#, Yuanfa Yao#, Qiulan Liu, Yingke Xu, Cuifang Kuang*, Haifeng Li*, Xu Liu, Assessment of tissues’ inhomogeneous optical properties based on a portable microscope under partially coherent illumination, Optics Communications, 434, 145–151(2019).
[18] Yinxu Bian, Wensheng Wang, Anwar Hussian, Cuifang Kuang*, Haifeng Li*, and Xu Liu, Experimental analysis and designing strategies of lens-less microscopy with partially coherent illumination, Optics Communications , 434, 136-144(2019).
2018
[1] Youhua Chen#, Wenjie Liu#, Zhimin Zhang, Cheng Zheng, Yujia Huang, Ruizhi Cao, Dazhao Zhu, Liang Xu, Meng Zhang, Yu-Hui Zhang, Jiannan Fan, Luhong Jin, Yingke Xu, Cuifang Kuang*, Xu Liu*, Multi-color live-cell super-resolution volume imaging with multi-angle interference microscopy, Nature Communications, 9, 4818 (2018).
[2] Ruizhi Cao, Youhua Chen, Wenjie Liu, Dazhao Zhu, Cuifang Kuang*, Yingke Xu*, and Xu Liu, Inverse matrix based phase estimation algorithm for structured illumination microscopy, Biomed. Opt. Express 9, 5037-5051 (2018).
[3] Dazhao Zhu#, Wenjie Liu#, Zhimin Zhang, Cheng Zheng, Youhua Chen, Chuankang Li, Cuifang Kuang*, Xu Liu, and Anwar Hussain, Enhancement of fluorescence emission difference microscopy using conjugated vortex phase modulation, Journal of Microscopy, 2018
[4] Yinxu Bian#, Qiulan Liu#, Zhifeng Zhang, Diyi Liu, Anwar Hussian, Cuifang Kuang*, Haifeng Li*, Xu Liu, Portable multi-spectral lens-less microscope with wavelength-self-calibrating imaging sensor, Optics and Lasers in Engineering, 111, 25-33 (2018).
[5] Vannhu Le, Xiaona Wang, Cuifang Kuang, Xu Liu*, Background suppression in confocal scanning fluorescence microscopy with superoscillations, Optics Communications, 426, 541-546 (2018).
[6] Levan Nhu#, Xiaona Wang#, Yong Liu, Cuifang Kuang*, Xu Liu, Light sheet microscopy with high spatial resolution based on polarized structured illumination beam modulated by the phase mask, Microsc Res Tech. 2018;81:959–965.
[7] Douguo Zhang, Liangfu Zhu, Junxue Chen, Ruxue Wang, Pei Wang, Hai Ming, Ramachandram Badugu, Mary Rosenfeld, Qiwen Zhan, Cuifang Kuang, Xu Liu* and Joseph R Lakowicz*, Conversion of isotropic fluorescence into a long-range non-diverging beam, Methods and applications in fluorescence, 2018, 6(2): 024003.
[8] Liu Y, Zhang Z, Li C, Liu D, Kuang C*. Rotating light fields of an azimuthally polarized light beam generated by two-belt spiral phase modulation[J]. Journal of Modern Optics, 2018: 1-6.
[9] Liu Y, Zhang Z, Cao R, Kuang C*. Tightly focused field modulated by spiral phase with an off-axis singularity[J]. Applied Physics B, 2018, 124(8): 157.
[10] Sun S, Liu S, Wang W, Zhang Z, Kuang C*, Liu X. Improving the resolution of two-photon microscopy using pixel reassignment[J]. Applied Optics, 2018, 57(21): 6181-6187.
[11] W. Liu, K. Toussaint Jr., C. Okoro, D. Zhu, Y. Chen, C. Kuang*, X. Liu, Breaking the axial diffraction limit: A guide to axial super-resolution fluorescence microscopy, Laser & Photonics Reviews, (2018) 1700333.
[12] G. Zhao#, C. Zheng#, C. Kuang*, R. Zhou, M. Kabir, K. Toussaint Jr., W. Wang, L. Xu, H. Li, P. Xiu, X. Liu, Nonlinear focal modulation microscopy, Physical Review Letters, 2018, 120(19): 193901. (# co-first author) (cover paper)
[13] V. Le , X. Wang, C. Kuang, X. Liu*, Resolution enhancement of confocal scanning microscopy using low-intensity imaging part of point spread function, Optical Engineering, 2018, 57(5): 053106.
[14] C. Li, C. Kuang*, X. Liu. Prospects for Fluorescence Nanoscopy, ACS nano, 2018.
[15] Y. Chen, R. Cao, W. Liu, D. Zhu, Z. Zhang, C. Kuang*, X. Liu, Widefield and total internal reflection fluorescent structured illumination microscopy with scanning galvo mirrors, Journal of Biomedical Optics, 23(2), 046007 (2018).
[16] W. Wang, G. Zhao, C. Kuang*, L. Xu, S. Liu, S. Sun, P. Shentu, Y. Yang, Y. Xu, X. Liu*, Integrated dual-color stimulated emission depletion (STED) microscopy and fluorescence emission difference (FED) microscopy, Optics Communications, 423 (2018) 167–174.
[17] S. Liu, Z. Zhang, J. Zheng, L. Xu, C. Kuang*, X. Liu, Parallelized fluorescence lifetime imaging microscopy (FLIM) based on photon reassignment. Optics Communications, 421 (2018) 83–89.
[18] C. Li, S. Liu, W. Wang, W. Liu, C. Kuang*, X. Liu, Recent research on stimulated emission depletion microscopy for reducing photobleaching. Journal of Microscopy, (2018), doi:10.1111/jmi.12698
[19] C. Zheng, G. Zhao, W. Liu, Y. Chen, Z. Zhang, L. Jin, Y. Xu, C. Kuang*, X. Liu, Three-dimensional super-resolved live cell imaging through polarized multi-angle TIRF, Optics Letters, 43 (2018) 1423-1426.
[20] Zhongzhi Yu#, Shaocong Liu#, Shiyi Sun, Cuifang Kuang*, Xu Liu. Imaging resolution and properties analysis ofsuper resolutionmicroscopy with parallel detection under different noise, detectorandimage restoration conditions[J]. Journal of Modern Optics, 2018, 65(10): 1188-1198.
[21] V. Le, C. Kuang, X. Liu*, Extended depth-of-field imaging by both radially symmetrical conjugating phase masks with spatial frequency post-processing, Optics Communications, 411 (2018) 80–872.
[22] Cheng Zheng, Guangyuan Zhao, Wenjie Liu, Youhua Chen, Zhimin Zhang, Luhong Jin, Yingke Xu, Cuifang Kuang* , Xu Liu. 3D super-resolved multi-angle TIRF via polarization modulation[J]. arXiv preprint arXiv:1801.00882, 2018.
2017
[1] R. Cao, C. Kuang*, Y. Liu, X. Liu, Superresolution via saturated virtual modulation microscopy, Optics Express 25 (2017) 32 364-32379
[2] A. Hussain, Y. Li, D. Liu, C. Kuang, X. Liu*, Lensless imaging through multiple phase patterns illumination, Journal of Biomedical Optics, 22(11) (2017) 110502.
[3] A. Hussain, Y. Li, D. Liu, C. Kuang, X. Liu*, On-chip Microscopy Using Random Phase Mask Scheme, Scientific Reports, (2017)7: 14768.
[4] V. Le, C. Kuang, X. Liu*, Optimization of wavefront coding systems based on the use of multitarget optimization, Optical Engineering, 56(9), (2017) 093102.
[5] G. Zhao, C. Zheng, C. Kuang*, X. Liu, Resolution-enhanced SOFI via structured illumination, Optics Letters, 42 (2017) 3956-3959.
[6] C. Zheng, G. Zhao, C. Kuang*, X. Liu, 3D point scanning super-resolution microscopy via polarization modulation, Optics Letters, 42 (2017)3734-3737.
[7] D. Zhu, Y. Chen, Y. Fang, A. Hussain, C. Kuang*, X. Zhou, Y. Xu, X. Liu, Compact three-dimensional super-resolution system based on fluorescence emission difference microscopy, Optics Communications, 405 (2017) 157-163.
[8] R. Cao, T. Yang, Y. Fang, C. Kuang*, and X. Liu, Pattern-illuminated Fourier ptychography microscopy with a pattern-estimation algorithm, Applied Optics, 56 (2017) 6930-6935.
[9] 赵光远, 郑程, 方月, 等. 基于点扫描的超分辨显微成像进展[J]. 物理学报, 2017, 66(14): 148702-148702. (Invited)
[10] S. Sun, S. Liu, C. Kuang*, X. Liu, Two-photon microscopy with enhanced contrast and resolution, Applied Optics, 56 (2017) 3799-3805.
[11] A. Hussain, T. Amin, C. Kuang, L. Cao, X. Liu*, Simple fringe illumination technique for optical superresolution, J. Opt. Soc. Am. B, 34 (2017) B78-B84.
[12] C. Zheng, R. Zhou*, C. Kuang, G. Zhao, Z. Yaqoob, P.T.C. So, Digital micromirror device-based common-path quantitative phase imaging, Optics Letters, 42 (2017) 1448-1451.
[13] Y. Huang, D. Zhu, L. Jin, C. Kuang, Y. Xu*, X. Liu, Laser scanning saturated structured illumination microscopy based on phase modulation, Optics Communications 396 (2017) 261–266.
[14] H. Li, L. Ou, J. Fan, M. Xiao, C. Kuang, X. Liu, Y. Sun, Y. Xu*, Rab8A regulates insulin‐stimulated GLUT4 translocation in C2C12 myoblasts, FEBS letters, (2017).
[15] R. Zhou*, D. Jin, P. Hosseini, V.R. Singh, Y.H. Kim, C. Kuang, R.R. Dasari, Z. Yaqoob, P.T. So, Modeling the depth-sectioning effect in reflection-mode dynamic speckle-field interferometric microscopy, Optics Express, 25 (2017) 130.
[16] Y. Li, S. Liu, D. Liu, S. Sun, C. Kuang*, Z. Ding, X. Liu*, Image scanning fluorescence emission difference microscopy based on a detector array, Journal of Microscopy, (2017), JT3A.61.
[17] G. Zhao, M.M. Kabir, K.C. Toussaint, C. Kuang*, C. Zheng, Z. Yu, X. Liu, Saturated absorption competition microscopy, Optica, 4 (2017) 633-636.
[18] X. Liu, C. Kuang, X. Hao, C. Pang, P. Xu, H. Li, Y. Liu, C. Yu, Y. Xu, D. Nan, W. Shen, Y. Fang, L. He, X. Liu, Q. Yang*, Fluorescent Nanowire Ring Illumination for Wide-Field Far-Field Subdiffraction Imaging, Physical Review Letters, 118 (2017) 076101.
[19] C. Zheng, R. Zhou, C. Kuang*, G. Zhao, Z. Zhang, X. Liu, Diffraction phase microscopy realized with an automatic digital pinhole, Optics Communications, (2017).
[20] Y. Chen, D. Zhu, Y. Fang, C. Kuang*, X. Liu, A novel method for enhancing the lateral resolution and image SNR in confocal microscopy, Optics Communications, (2017).
[21] B. Ge, Y. Huang, Y. Fang, C. Kuang*, P. Xiu, X. Liu, Frequency domain phase-shifted confocal microscopy (FDPCM) with array detection, Journal of Modern Optics, (2017) 1-7.
[22] Z. Yu, S. Liu, D. Zhu, C. Kuang*, X. Liu, Parallel detecting super-resolution microscopy using correlation based image restoration, Optics Communications, (2017).
[23] F. Yang, C. Kuang, W. Zhao, G. Wang*, AC electrokinetic fast mixing in non-parallel microchannels, Chemical Engineering Communications, 204(2017)190–197.
[24] D. Zhu, Y. Fang, Y. Chen, A. Hussain, C. Kuang*, Z. Ding, X. Liu, Comparison of multi-mode parallel detection microscopy methods, Optics Communications, 387(2017) 275-280.
[25] D. Zhu, Y. Chen, C. Kuang*, X. Liu, Emission difference super-resolution microscopy with optical lattices scanning and wide field detection, Optics Communications, 395(2017)29–33.
[26] S. Liu, S. Sun, C. Kuang*, B. Ge, W. Wang, X. Liu, Saturated virtual fluorescence emission difference microscopy based on detector array, Optics Communications, 395(2017)45–50.
[27] Chenlei Pang, Xiaowei Liu, Minghua Zhuge, Xu Liu, Michael Geoffrey Somekh, Yiying Zhao, Di Jin, Weidong Shen, Haifeng Li, Lan Wu, Changhua Wang, Cuifang Kuang, and Qing Yang. High-contrast wide-field evanescent wave illuminated subdiffraction imaging[J]. Optics letters, 2017, 42(21): 4569-4572.
[28] Luhong Jin, Xiaoxu Zhou, Peng Xiu, Wei Luo, Yujia Huang, Feng Yu, Cuifang Kuang, Yonghong Sun, Xu Liu, Yingke Xu. Imaging and reconstruction of cell cortex structures near the cell surface[J]. Optics Communications, 2017, 402: 699-705.
[29] Zhang D, Wang R, Xiang Y, et al. Silver nanowires for reconfigurable Bloch surface waves[J]. ACS nano, 2017, 11(10): 10446-10451.
[30] L. Jin, J. Wu, P. Xiu, J. Fan, M. Hu, C. Kuang, Y. Xu*, X. Zheng, X. Liu, High-resolution 3D reconstruction of microtubule structures by quantitative multi-angle total internal reflection fluorescence microscopy, Optics Communications, (2016).
[31] Jiannan Fan, Xiaoxu Zhou, Yanli Wang, Cuifang Kuang, Yonghong Sun, Xu Liu, Derek Toomre, Yingke Xu*. Differential requirement for N‐ethylmaleimide‐sensitive factor in endosomal trafficking of transferrin receptor from anterograde trafficking of vesicular stomatitis virus glycoprotein G[J]. FEBS letters, 2017, 591(2): 273-281.
2016
[1] Q. Liu, Y. Fang, R. Zhou, P. Xiu, C. Kuang, X. Liu*, Surface wave illumination Fourier ptychographic microscopy, Optics Letters, 41 (2016) 5373-5376.
[2] Y. Fang, Y. Chen, C. Kuang*, P. Xiu, Q. Liu, B. Ge, X. Liu, Saturated pattern-illuminated Fourier ptychography microscopy, Journal of Optics, 19 (2016) 015602.
[3] H. Li, Y. Huang, C. Kuang*, X. Liu, Method of super-resolution based on array detection and maximum-likelihood estimation, Applied Optics, 55 (2016) 9925-9931.
[4] S. You, C. Kuang, B. Zhang*, Resolution criteria in double-slit microscopic imaging experiments, Scientific Reports, 6 (2016) 33764.
[5] G. Zhao, C. Kuang*, Z. Ding, X. Liu, Resolution enhancement of saturated fluorescence emission difference microscopy, Optics Express, 24 (2016) 23596-23609.
[6] Y. Huang, Y. Wang, C. Kuang*, X. Liu, Method for enhancing stability in multi-beam microscopy, Meas. Sci. Technol. 27 (2016) 105901
[7] C. Kuang*, Y. Ma, R. Zhou, G. Zheng, Y. Fang, Y. Xu, X. Liu, P.T. So, Virtual k-Space Modulation Optical Microscopy, Physical Review Letters, 117 (2016) 028102.
[8] P. Xiu, Y. Chen, C. Kuang*, Y. Fang, Y. Wang, J. Fan, Y. Xu, X. Liu, Structured illumination fluorescence Fourier ptychographic microscopy, Optics Communications, 381 (2016) 100-106.
[9] Q. Liu, C. Kuang*, Y. Fang, P. Xiu, Y. Li, R. Wen, X. Liu, Effect of spatial spectrum overlap on fourier ptychographic microscopy, Journal of Innovative Optical Health Sciences, (2016).
[10] G. Zhao, Z. Rong, C. Zheng, X. Liu, C. Kuang*, 3D fluorescence emission difference microscopy based on spatial light modulator, Journal of Innovative Optical Health Sciences, (2016).
[11] P. Hosseini, R. Zhou, Y.-H. Kim, C. Peres, A. Diaspro, C. Kuang, Z. Yaqoob, P.T. So*, Pushing phase and amplitude sensitivity limits in interferometric microscopy, Optics Letters, 41 (2016) 1656-1659.
[12] B. Ge, Y. Wang, Y. Huang, C. Kuang*, Y. Fang, P. Xiu, Z. Rong, X. Liu, Three-dimensional resolution and contrast-enhanced confocal microscopy with array detection, Optics Letters, 41 (2016) 2013-2016.
[13] S. Liu, S. You, Y. Fang, Y. Wang, C. Kuang*g, X. Liu, Effects of polarization and phase modulation on the focal spot in 4Pi microscopy, Journal of Modern Optics, (2016) 1-13.
2015
[1] B. Ge, L. Zhu, C. Kuang*, D. Zhang, Y. Fang, Y. Ma, X. Liu, 'Fluorescence emission difference with defocused surface plasmon-coupled emission microscopy,' Optics Express, 32561-32572 (2015).
[2] Y. Ma, C. Kuang*, Y. Fang, B. Ge, D. Li, X. Liu, ''Virtual fluorescence emission difference microscopy based on photon reassignment,'' Optics Letters, 4627-4630,40 (2015).
[3] C. Kuang, Y. Ma, R. Zhou, J. Lee, G. Barbastathis, R.R. Dasari, Z. Yaqoob, P.T.C. So, ''Digital micromirror device-based laser-illumination Fourier ptychographic microscopy,'' Optics Express, 26999-27010.23 (2015) .
[4] S. You, C. Kuang*, K.C. Toussaint, R. Zhou, X. Xia, X. Liu, ''Iterative phase-retrieval method for generating stereo array of polarization-controlled focal spots,'' Optics Letters, 3532-3535,40 (2015).
[5] L. Xue, C. Kuang*, Y. Fang, S. You, Y. Ma, X. Liu, ''Axial nanodisplacement measurement based on the double-helix point spread function generated using radially polarized beams with vortex phase modulation, '' Japanese Journal of Applied Physics 54, 082501 (2015).
[6] Z. Rong, C. Kuang*, Y. Fang, G. Zhao, Y. Xu, X. Liu, ''Super-resolution microscopy based on fluorescence emission difference of cylindrical vector beams,'' Optics Communications,71-78(2015).
[7] Y. Wang, Y. Ma, C. Kuang*, Y. Fang, Y. Xu, X. Liu, Z. Ding, ''Dual-mode super-resolution imaging with stimulated emission depletion microscopy and fluorescence emission difference microscopy,'' Applied Optics, 5425-5431,54 (2015).
[8] B. Ge, Y. Ma, C. Kuang*, D. Zhang, K.C. Toussaint, S. You, X. Liu, ''Resolution-enhanced surface plasmon-coupled emission microscopy,'' Optics Express,13159-13171,23(2015).
[9] P. Xiu, X. Zhou, C. Kuang*, Y. Xu, X. Liu, ''Phase microscopy using light-field reconstruction method for cell observation,'' Micron, 11-17,75 (2015) .
[10] H. Cai, Y. Wang, C. Kuang*, J. Ge, Y. Xu, X. Liu,'Sub-diffraction imaging with total internal reflection fluorescence (TIRF) microscopy by stochastic photobleaching,' Journal of Modern Optics, 1-6(2015).
[11] Y. Liu, C. Kuang*, X. Liu, ''The use of azimuthally polarized sinh-Gauss beam in STED microscopy,'' Journal of Optics, 045609.17(2015).
[12] S. You, C. Kuang*, S. Li, X. Liu, Z. Ding, ''Three-dimensional super-resolution imaging for fluorescence emission difference microscopy,'' AIP Advances, 084901. 5 (2015).
[13] Y. Ma, C. Kuang*, W. Gong, L. Xue, Y. Zheng, Y. Wang, K. Si, X. Liu, ''Improvements of axial resolution in confocal microscopy with fan-shaped apertures,' Applied Optics, 54,1354-1362(2015) .
[14] Y. Fang, C. Kuang, Y. Ma, Y. Wang, X. Liu*, 'Resolution and contrast enhancements of optical microscope based on point spread function engineering,' Frontiers of Optoelectronics, 1-11 (2015).
[15] Y. Ma, C. Kuang*, Y. Fang, B. Ge, X. Mao, S. Shen, Y. Xu, X. Liu, ''Particle localization with total internal reflection illumination and differential detection,'' Optics Communications, 339,14-21(2015).
[16] Y. Zhu, S. Liu, C. Kuang*, S. Li, X. Liu, Roll angle measurement based on common path compensation principle, Optics and Lasers in Engineering, 67, 66-73 (2015).
[17] P. Xiu, X. Zhou, C. Kuang*, Y. Xu, X. Liu,' Controllable tomography phase microscopy,' Optics and Lasers in Engineering, 66, 301-306 (2015).
[18] P. Zhang, Y. Wang, C. Kuang*, S. Li and X. Liu, 'Measuring roll angle displacement based on ellipticity with high resolution and large range,' Optics & Laser Technology 65(0), 126-130 (2015)
[19] Wang R, Zhang D, Zhu L, et al. Selectable surface and bulk fluorescence imaging with plasmon-coupled waveguides[J]. The Journal of Physical Chemistry C, 2015, 119(38): 22131-22136.
2014
[1] Y. liu, C. Kuang*, X. Liu,''A method for achieving multiple foci with subdiffraction resolution along the axial direction,' Journal of Modern Optics, pp.1-5(2014).
[2] S. You, C. Kuang*, Z Rong, X Liu, Z. Ding'Isotropic superresolution imaging for fluorescence emission difference microscopy'Applied Optics Vol. 53, Iss. 33, pp. 7838–7844 (2014)
[3] S. You, C. Kuang*, Z. Rong, X. Liu, Eliminating deformations in fluorescence emission difference microscopy, Opt Express, 22 (2014) 26375-26385.
[4] Y. Wang, C. Kuang*, S. Li, X. Hao, Y. Xu, X. Liu, A 3D aligning method for stimulated emission depletion microscopy using fluorescence lifetime distribution, Microscopy research and technique, 77:935–940 (2014).
[5] Z. Rong, S. Li, C. Kuang*, Y. Xu, X. Liu, Real-time super-resolution imaging by high-speed fluorescence emission difference microscopy, Journal of Modern Optics,1-8, (2014)
[6] Y. Ma, Y. Wang, X. Zhou, C. Kuang* and X. Liu, '3D dual-virtual-pinhole assisted single particle tracking microscopy,' Journal of Optics 16(7), 075703 (2014)
[7] 修鹏,江芸珊,王轶凡,匡翠方,李帅,刘旭. 一种柱状矢量偏振光的检测与评价方法[J]. 光学学报, 2014, 34(6): 0612002
[8] Y Fang,Y Wang,C Kuang*, et al. Enhancing the resolution and contrast in CW-STED microscopy. Optics Communications, (2014)
[9] C Jiang,C Kuang*,S Li, et al. Arbitrary three-dimensional polarization control based on cylindrical vector beams and binary phase coding. Journal of Modern Optics,1-7, (2014)
[10] Y. Wang, C. Kuang*, H. Cai, S. Li, W. Liu, X. Hao, J. Ge, X. Liu, Sub-diffraction imaging with confocal fluorescence microscopy by stochastic photobleaching, Optics Communications, 312,62-67.(2014)
[11] Y. Wang, C. Kuang*, P. Xiu, S. Li, X. Hao, X. Liu, A lateral differential confocal microscopy for accurate detection and localization of edge contours, Optics and Lasers in Engineering, 53, 12-18. (2014)
[12] Y. Hu, S. Li, C. Kuang*, P. Xiu, J. Ge and X. Liu, 'An axial displacement measurement relying on the double-helix light beam,' Optics & Laser Technology 59(0), 1-6 (2014)
[13] Su C, Xia X, Li H, et al. A penetrable interactive 3D display based on motion recognition[J]. Chinese Optics Letters, 2014, 12(6): 060007.
京公网安备 11010802027423号