基本信息
董慧 女 博导 中国科学院上海微系统与信息技术研究所
电子邮件: donghui@mail.sim.ac.cn
通信地址: 上海市嘉定区城北路235号3号楼1112室
邮政编码:
电子邮件: donghui@mail.sim.ac.cn
通信地址: 上海市嘉定区城北路235号3号楼1112室
邮政编码:
教育背景
2008-07--2010-10 德国于利希研究中心 联合培养博士生2006-09--2011-06 中国科学院上海微系统与信息技术研究所 工学博士2002-09--2006-06 武汉大学 物理科学与技术学院 工学学士
专利与奖励
专利成果
[1] 董慧, 李永强, 杨思维, 陶泉, 丁古巧, 谢晓明. 一种顺磁性手性石墨烯量子点及其制备方法和用途. CN: CN113234442A, 2021-08-10.[2] 荣亮亮, 代海宾, 伍俊, 邱隆清, 宋正威, 董慧, 陶泉, 裴易峰, 谢晓明. 一种磁场总场的补偿方法、装置、系统及存储介质. CN: CN111413651B, 2021-04-13.[3] 董慧, 李永强, 杨思维, 丁古巧, 谢晓明. 一种高弛豫率双模态造影剂的制备方法. CN: CN111714645B, 2021-04-09.[4] 陶泉, 董慧, 刘少杰, 荣亮亮, 谢晓明. 一种极低场核磁共振成像系统及其基线校准方法. CN: CN112611994A, 2021-04-06.[5] 董慧, 李永强, 杨思维, 丁古巧, 谢晓明. 基于生物传感器来检测生物标志物的核磁共振检测方法及试剂盒. CN: CN112540097A, 2021-03-23.[6] 周丹峰, 李杰, 董慧, 谭亦秋, 宋勐潇, 余佩倡. 用于低场核磁共振的预极化线圈电流控制系统及控制方法. CN: CN109980743B, 2020-12-29.[7] 董慧, 李永强, 杨思维, 丁古巧, 谢晓明. 一种双模态造影剂的制备方法. CN: CN111714646A, 2020-09-29.[8] 邱隆清, 翟俊奇, 伍俊, 荣亮亮, 董慧, 裴易峰, 陶泉, 张国峰. 一种超导磁测系统角度误差的校正方法及存储介质. CN: CN111077595A, 2020-04-28.[9] 黄小磊, 邱阳, 董慧, 陶泉, 李波. 基于SQUID一阶梯度计的工频噪声抑制装置. 中国: CN106814338A, 2017-06-09.[10] 邱阳, 董慧, 黄小磊, 陶泉, 李波. 基于SQUID磁强计的工频噪声抑制装置. 中国: CN106772141A, 2017-05-31.[11] 董慧, 邱阳, 黄小磊, 陶泉, 李波. 基于SQUID二阶梯度计的工频噪声抑制装置. 中国: CN106707199A, 2017-05-24.[12] 邱阳, 董慧, 黄小磊, 陶泉, 李波. 基于SQUID三轴磁强计的工频噪声抑制装置. 中国: CN106680746A, 2017-05-17.[13] 伍俊, 荣亮亮, 王会武, 王永良, 常凯, 侍文, 董慧, 蒋坤, 谢晓明. 一种基于超导磁传感器的数字化实时磁场补偿装置及方法. 中国: CN103389478A, 2013-11-13.[14] 伍俊, 荣亮亮, 王会武, 王永良, 常凯, 侍文, 董慧, 蒋坤, 谢晓明. 一种超导量子干涉仪的数字化模拟器. 中国: CN103389482A, 2013-11-13.[15] 邱隆清, 董慧, 侍文, 徐璐, 常宝林, 谢晓明. 基于空间相关性的空间磁场及全张量梯度测量系统及方法. 中国: CN103293493A, 2013-09-11.[16] 徐璐, 邱隆清, 董慧, 谢晓明. 一种基于永磁铁和自动传输装置的样品极化系统. 中国: CN102901662A, 2013-01-30.[17] 荣亮亮, 张国峰, 董慧, 王永良, 王会武, 谢晓明, 江绵恒. 基于SQUID偏置电压反转的读出电路及低频噪声的抑制方法. 中国: CN102426343A, 2012.04.25.[18] 张懿, H-J·克劳斯, N·沃尔特斯, A·奥芬豪瑟, 谢晓明, 王会武, 王永良, 董慧. 具有经由互感感应耦合到SQUID的线圈的SQUID. 中国: CN102483444A, 2012-05-30.[19] 荣亮亮, 王永良, 董慧, 王会武, 谢晓明, 江绵恒. 基于三端变压器的超导SQUID偏置反转前端电路及调整方法. 中国: CN102426342A, 2012-04-25.[20] 荣亮亮, 王永良, 王会武, 邱隆清, 董慧, 谢晓明, 江绵恒. 基于扰动补偿的环境场下高灵敏度磁测量装置及实现方法. 中国: CN102353911A, 2012-02-15.
出版信息
发表论文
[1] Yongqiang Li, Yi Xiao, Quan Tao, Mengmeng Yu, Li Zheng, Siwei Yang, Guqiao Ding, Hui Dong, Xiaoming Xie. Selective coordination and localized polarization in graphene quantum dots: Detection of fluoride anions using ultra-low-field NMR relaxometry. Chinese Chemical Letters. 2021, 32(12): 3921-3926, [2] 李春光, 王佳, 吴云, 王旭, 孙亮, 董慧, 高波, 李浩, 尤立星, 林志荣, 任洁, 李婧, 张文, 贺青, 王轶文, 韦联福, 孙汉聪, 王华兵, 李劲劲, 屈继峰. 中国超导电子学研究及应用进展. 物理学报. 2021, 70(1): 178-203, http://lib.cqvip.com/Qikan/Article/Detail?id=7103797807.[3] Li, Yongqiang, Ma, Peixiang, Tao, Quan, Krause, HansJoachim, Yang, Siwei, Ding, Guqiao, Dong, Hui, Xie, Xiaoming. Magnetic graphene quantum dots facilitate closed-tube one-step detection of SARS-CoV-2 with ultra-low field NMR relaxometry. SENSORS AND ACTUATORS B-CHEMICAL[J]. 2021, 337: 129786-129786, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7959688/.[4] Wang, Yongliang, Zhang, Guofeng, Zhang, Shulin, Dong, Hui, Rong, Liangliang, Wang, Yong, Xie, Xiaoming. A Practical Two-Stage SQUID Readout Circuit Improved With Proportional Feedback Schemes. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2020, 30(5): https://www.webofscience.com/wos/woscc/full-record/WOS:000526275200001.[5] Li, Yongqiang, Dong, Hui, Tao, Quan, Ye, Caichao, Yu, Mengmeng, Li, Jipeng, Zhou, Huifang, Yang, Siwei, Ding, Guqiao, Xie, Xiaoming. Enhancing the magnetic relaxivity of MRI contrast agents via the localized superacid microenvironment of graphene quantum dots. BIOMATERIALS[J]. 2020, 250: http://dx.doi.org/10.1016/j.biomaterials.2020.120056.[6] Xu, Anli, He, Peng, Ye, Caichao, Liu, Zhiduo, Gu, Bingli, Gao, Bo, Li, Yongqiang, Dong, Hui, Chen, Da, Wang, Gang, Yang, Siwei, Ding, Guqiao. Polarizing Graphene Quantum Dots toward Long-Acting Intracellular Reactive Oxygen Species Evaluation and Tumor Detection. ACS APPLIED MATERIALS & INTERFACES[J]. 2020, 12(9): 10781-10790, https://www.webofscience.com/wos/woscc/full-record/WOS:000518702300074.[7] Wang, Yongliang, Zhang, Guofeng, Dong, Hui, Zhang, Shulin, Rong, Liangliang, Pei, Yifeng, Qiu, Longqing, Wu, Jun, Wang, Yong, Xie, Xiaoming. Wide Range SQUID Amplifier With Proportional Feedback for Flux Quanta Counting Scheme. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2020, 30(5): https://www.webofscience.com/wos/woscc/full-record/WOS:000522224500001.[8] Yu, Mengmeng, Tao, Quan, Dong, Hui, Huang, Tao, Li, Yongqiang, Xiao, Yi, Yang, Siwei, Gao, Bo, Ding, Guqiao, Xie, Xiaoming. Ultra-low noise graphene/copper/nylon fabric for electromagnetic interference shielding in ultra-low field magnetic resonance imaging. JOURNAL OF MAGNETIC RESONANCE[J]. 2020, 317: http://dx.doi.org/10.1016/j.jmr.2020.106775.[9] Xu, Anli, Wang, Gang, Li, Yongqiang, Dong, Hui, Yang, Siwei, He, Peng, Ding, Guqiao. Carbon-Based Quantum Dots with Solid-State Photoluminescent: Mechanism, Implementation, and Application. SMALLnull. 2020, 16(48): https://www.webofscience.com/wos/woscc/full-record/WOS:000584488800001.[10] Song, Zhengwei, Dai, Haibin, Rong, Liangliang, Dong, Hui, Wu, Jun, Qiu, Longqing, Zhang, Guofeng, Wang, Yongliang, Tao, Quan, Pei, Yifeng, Zhang, Shulin, Xie, Xiaoming. Noise Compensation of a Mobile LTS SQUID Planar Gradiometer for Aeromagnetic Detection. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2019, 29(8): https://www.webofscience.com/wos/woscc/full-record/WOS:000565193500001.[11] Dong, Hui, Chang, Songtao, Qiu, Yang, Tao, Quan, Huang, Xiaolei, Pei, Yifeng, Rong, Liangliang. Simulation and Measurements of Transient Fields From Conductive Plates of Shielded Room for SQUID-Based Ultralow Field Magnetic Resonance Imaging. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2019, 29(7): https://www.webofscience.com/wos/woscc/full-record/WOS:000471024900001.[12] Rong, Liangliang, Bao, Suxin, Wu, Jun, Zhang, Guofeng, Qiu, Longqing, Zhang, Shulin, Wang, Yongliang, Dong, Hui, Pei, Yifeng, Xie, Xiaoming. High-Performance Dual-Channel Squid-Based TEM System and Its Application. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2019, 29(8): https://www.webofscience.com/wos/woscc/full-record/WOS:000475340400001.[13] Huang, Xiaolei, Dong, Hui, Tao, Quan, Yu, Mengmeng, Li, Yongqiang, Rong, Liangliang, Krause, HansJoachim, Offenhaeusser, Andreas, Xie, Xiaoming. Sensor Configuration and Algorithms for Power-Line Interference Suppression in Low Field Nuclear Magnetic Resonance. Sensors[J]. 2019, 19(16): https://doaj.org/article/cd71ea4b0fd44fcaa809fdbac132485d.[14] Dong Hui. Performance study of aluminum shielded room for ultra-low-field magnetic resonance imaging based on SQUID: Simulations and experiments. Chin. Phys. B. 2018, [15] Huang, Xiaolei, Dong, Hui, Qiu, Yang, Li, Bo, Tao, Quan, Zhang, Yi, Krause, HansJoachim, Offenhaeusser, Andreas, Xie, Xiaoming. Adaptive suppression of power line interference in ultra-low field magnetic resonance imaging in an unshielded environment. JOURNAL OF MAGNETIC RESONANCE[J]. 2018, 286: 52-59, http://dx.doi.org/10.1016/j.jmr.2017.11.009.[16] Dong, Hui, Hwang, Seongmin, Wendland, Michael, You, Lixing, Clarke, John, Inglis, Ben. Ultralow-field and spin-locking relaxation dispersion in postmortem pig brain. MAGNETIC RESONANCE IN MEDICINE[J]. 2017, 78(6): 2342-2351, https://www.webofscience.com/wos/woscc/full-record/WOS:000414967400028.[17] Wang, Wei, Ma, Peixiang, Dong, Hui, Krause, HansJoachim, Zhang, Yi, Willbold, Dieter, Offenhaeusser, Andreas, Gu, Zhongwei. A magnetic nanoparticles relaxation sensor for protein-protein interaction detection at ultra-low magnetic field. BIOSENSORS & BIOELECTRONICS[J]. 2016, 80: 661-665, http://dx.doi.org/10.1016/j.bios.2016.02.037.[18] Huang, Ruiqi, Tao, Quan, Chang, Baolin, Dong, Hui. Field Dependence Study of Commercial Gd Chelates With SQUID Detection. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2016, 26(5): [19] Dong Hui. Ultra-low-field-MRI in "SQUIDs in biomagnetism: a roadmap towards improved healthcare". Supercond. Sci. Technol.. 2016, [20] Liu, Chao, Chang, Baolin, Qiu, Longqing, Dong, Hui, Qiu, Yang, Zhang, Yi, Krause, HansJoachim, Offenhaeusser, Andreas, Xie, Xiaoming. Effect of magnetic field fluctuation on ultra-low field MRI measurements in the unshielded laboratory environment. JOURNAL OF MAGNETIC RESONANCE[J]. 2015, 257: 8-14, http://dx.doi.org/10.1016/j.jmr.2015.04.014.[21] Zevenhoven, Koos C J, Dong, Hui, Ilmoniemi, Risto J, Clarke, John. Dynamical cancellation of pulse-induced transients in a metallic shielded room for ultra-low-field magnetic resonance imaging. APPLIED PHYSICS LETTERS[J]. 2015, 106(3): http://dx.doi.org/10.1063/1.4906058.[22] Liu, Chao, Chang, Baolin, Qiu, Longqing, Qiu, Yang, Dong, Hui, Zhang, Yi, Xie, Xiaoming. Multichannel ULF-MRI Study in Magnetic Unshielded Urban Laboratory Environment. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2015, 25(4): https://www.webofscience.com/wos/woscc/full-record/WOS:000355258600001.[23] Liu, Chao, Zhang, Yi, Dong, Hui, Qiu, Longqing, Krause, HansJoachim, Xie, Xiaoming, Offenhaeusser, Andreas. Tuned HTS SQUID-Detected Low Field MRI Using a Permanent Magnet for Pre-polarization With Automatic Transportation. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2013, 23(3): https://www.webofscience.com/wos/woscc/full-record/WOS:000314283800042.[24] Dong, Hui, Qiu, Longqing, Shi, Wen, Chang, Baolin, Qiu, Yang, Xu, Lu, Liu, Chao, Zhang, Yi, Krause, HansJoachim, Offenhaeusser, Andreas, Xie, Xiaoming. Ultra-low field magnetic resonance imaging detection with gradient tensor compensation in urban unshielded environment. APPLIED PHYSICS LETTERS[J]. 2013, 102(10): https://www.webofscience.com/wos/woscc/full-record/WOS:000316501200054.[25] Qiu Longqing, Liu Chao, Dong Hui, Xu Lu, Zhang Yi, Krause HansJoachim, Xie Xiaoming, Kes PH, Rogalla H. Magnetic Field Improved ULF-NMR Measurement in an Unshielded Laboratory Using a Low-Tc SQUID. SUPERCONDUCTIVITY CENTENNIAL CONFERENCE 2011null. 2012, 36: 388-393, [26] 邱隆清, 刘超, 董慧, 徐璐, 张懿, HansJoachim, Krause, 谢晓明, Andreas, Offenhusser. Time-Domain Frequency Correction Method for Averaging Low-Field NMR Signals Acquired in Urban Laboratory Environment. CHINESE PHYSICS LETTERS[J]. 2012, 29(10): 213-216, http://ir.sim.ac.cn/handle/331004/114856.[27] Wang, Wei, Pacheco, Victor, Krause, HansJoachim, Zhang, Yi, Dong, Hui, Hartmann, Rudolf, Willbold, Dieter, Offenhaeusser, Andreas, Gu, Zhongwei. Size and Compositional Effects on Contrast Efficiency of Functionalized Superparamagnetic Nanoparticles at Ultralow and Ultrahigh Magnetic Fields. JOURNAL OF PHYSICAL CHEMISTRY C[J]. 2012, 116(33): 17880-17884, http://ir.sim.ac.cn/handle/331004/115219.[28] Zhang, Guofeng, Zhang, Yi, Zhang, Shulin, Krause, HansJoachim, Wang, Yongliang, Liu, Chao, Zeng, Jia, Qiu, Yang, Kong, Xiangyan, Dong, Hui, Xie, Xiaoming, Offenhaeusser, Andreas, Jiang, Mianheng. A SQUID gradiometer module with wire-wound pickup antenna and integrated voltage feedback circuit. PHYSICA C-SUPERCONDUCTIVITY AND ITS APPLICATIONS[J]. 2012, 480: 10-13, http://dx.doi.org/10.1016/j.physc.2012.04.023.[29] Zhang, Guofeng, Zhang, Yi, Dong, Hui, Krause, HansJoachim, Xie, Xiaoming, Braginski, Alex I, Offenhausser, Andreas, Jiang, Mianheng. Parameter tolerance of the SQUID bootstrap circuit. SUPERCONDUCTOR SCIENCE & TECHNOLOGY[J]. 2012, 25(1): http://ir.sim.ac.cn/handle/331004/114810.[30] Dong, Hui, Zhang, Guofeng, Wang, Yongliang, Zhang, Yi, Xie, Xiaoming, Krause, HansJoachim, Braginski, Alex I, Offenhaeusser, Andreas. Effect of voltage source internal resistance on the SQUID bootstrap circuit. SUPERCONDUCTOR SCIENCE & TECHNOLOGY[J]. 2012, 25(1): http://ir.sim.ac.cn/handle/331004/114763.[31] Liu, Chao, Zhang, Yi, Dong, Hui, Qiu, Longqing, Krause, HansJoachim, Xie, Xiaoming, Offenhaeusser, Andreas. Low-field MRI detected by tuned HTS SQUID utilizing permanent magnet as pre-polarization field. BIOMEDICAL ENGINEERING-BIOMEDIZINISCHE TECHNIK[J]. 2012, 57: 213-213, https://www.webofscience.com/wos/woscc/full-record/WOS:000497706300111.[32] Zhang, Yi, Zhang, Guofeng, Wang, Huiwu, Wang, Yongliang, Dong, Hui, Xie, Xiaoming, Mueck, Michael, Krause, HansJoachim, Braginski, Alex I, Offenhaeusser, Andreas, Jiang, Mianheng. Comparison of Noise Performance of the dc SQUID Bootstrap Circuit With That of the Standard Flux Modulation dc SQUID Readout Scheme. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2011, 21(3): 501-504, http://ir.sim.ac.cn/handle/331004/115186.[33] Zhang, Guofeng, Zhang, Yi, Dong, Hui, Krause, HansJoachim, Xie, Xiaoming, Braginski, Alex I, Offenhaeusser, Andreas, Jiang, Mianheng. An approach to optimization of the superconducting quantum interference device bootstrap circuit. SUPERCONDUCTOR SCIENCE & TECHNOLOGY[J]. 2011, 24(6): http://www.irgrid.ac.cn/handle/1471x/390913.[34] Dong, Hui, Zhang, Yi, Krause, HansJoachim, Xie, Xiaoming, Offenhaeusser, Andreas. Low Field MRI Detection With Tuned HTS SQUID Magnetometer. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2011, 21(3): 509-513, http://www.irgrid.ac.cn/handle/1471x/390908.[35] Wang, Wei, Dong, Hui, Pacheco, Victor, Willbold, Dieter, Zhang, Yi, Offenhaeusser, Andreas, Hartmann, Rudolf, Weirich, Thomas E, Ma, Peixiang, Krause, HansJoachim, Gu, Zhongwei. Relaxation Behavior Study of Ultrasmall Superparamagnetic Iron Oxide Nanoparticles at Ultralow and Ultrahigh Magnetic Fields. JOURNAL OF PHYSICAL CHEMISTRY B[J]. 2011, 115(49): 14789-14793, http://ir.sim.ac.cn/handle/331004/106802.[36] 董慧. 基于超导量子干涉器件的极低场NMR/MRI研究. 2011, http://ir.sim.ac.cn/handle/331004/83518.[37] Wang, Yongliang, Xie, Xiaoming, Dong, Hui, Zhang, Guofeng, Wang, Huiwu, Zhang, Yi, Mueck, Michael, Krause, HansJoachim, Braginski, Alex I, Offenhaeusser, Andreas, Jiang, Mianheng. Voltage Biased SQUID Bootstrap Circuit: Circuit Model and Numerical Simulation. IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY[J]. 2011, 21(3): 354-357, http://www.irgrid.ac.cn/handle/1471x/390926.[38] Dong Hui, Zhang Yi, Krause, HansJoachim, Xie XiaoMing. Effect of HTS Superconductors on Homogeneity of Measurement Field in Low Field Nuclear Magnetic Resonance Detection. CHINESE PHYSICS LETTERS[J]. 2010, 27(8): http://lib.cqvip.com/Qikan/Article/Detail?id=34691872.[39] 董慧, 张懿, KRAUSE, Hans-Joachim, 谢晓明. Effect of HTS Superconductors on Homogeneity of Measurement Field in Low Field Nuclear Magnetic Resonance Detection. 中国物理快报:英文版. 2010, 27(8): 250-252, http://lib.cqvip.com/Qikan/Article/Detail?id=34691872.[40] Dong, Hui, Zhang, Yi, Krause, HansJoachim, Xie, Xiaoming, Braginski, Alex I, Offenhaeusser, Andreas. Suppression of ringing in the tuned input circuit of a SQUID detector used in low-field NMR measurements. SUPERCONDUCTOR SCIENCE & TECHNOLOGY[J]. 2009, 22(12): http://ir.sim.ac.cn/handle/331004/94880.[41] Dong, Hui, Wang, Yongliang, Zhang, Shulin, Sun, Yue, Xie, Xiaoming. Detection of proton NMR signal in the Earth's magnetic field at an urban laboratory environment without shielding. SUPERCONDUCTOR SCIENCE & TECHNOLOGY[J]. 2008, 21(11): http://ir.sim.ac.cn/handle/331004/95004.
发表著作
(1) Biomagnetic Sensing. In: Springer Series on Chemical Sensors and Biosensors (Methods and Applications), Springer, 2017-08, 第 2 作者(2) SQUID Readout Electronics and Magnetometric Systems for Practical Applications, Wiley-VCH, 2020-05, 第 2 作者
科研活动
科研项目
( 1 ) 超顺磁性石墨烯-Fe3O4复合纳米粒子对极低场磁共振弛豫时间的影响研究, 主持, 国家级, 2013-01--2015-12( 2 ) 极低场下磁共振纵向弛豫时间(T1)加权成像研究, 主持, 省级, 2012-10--2015-09( 3 ) 中国科学院青年创新促进会资助项目, 主持, 部委级, 2012-01--2015-12( 4 ) 超导电子器件应用基础研究, 参与, 部委级, 2012-09--2017-06( 5 ) 全自主极低场磁共振系统样机及生物检测应用演示, 主持, 省级, 2019-09--2021-08( 6 ) Novel contrast agents study for ultra-low field magnetic resonance imaging with different prepolarization techniques, 主持, 国家级, 2020-01--2022-12( 7 ) 生物组织模型在极低磁场下的核磁共振弛豫机理研究, 主持, 国家级, 2019-01--2022-12( 8 ) 基于融合光刻工艺的超导磁传感器研制, 主持, 国家级, 2021-12--2024-11
参与会议
(1)极低场磁共振系统及其在生物磁学的应用研究 第二届生物磁学与磁性纳米材料学术会议 2020-12-12(2)基于SQUID的极低场磁共振系统及其应用研究 第十六届全国超导薄膜和超导电子器件学术研讨会 2020-11-22(3)Improvement of low-Tc SQUID base ultra-low field magnetic resonance system 2019-07-28(4)极低场磁共振系统与应用研究 生物检测与影像技术”新微技术论坛 2019-06-05(5)Low-Tc SQUID based ultra-low field magnetic resonance imaging: system and applications 2019-05-23(6)Adaptive suppression of power line interference in ultra-low field magnetic resonance imaging in an unshielded environment 2018-10-28(7)基于SQUID检测的极低场磁共振成像环境干扰抑制技术研究 第十五届全国超导薄膜和超导电子器件学术研讨会 2018-10-15(8)Environmental noise suppress techniques for unshielded ultra-low magnetic resonance imaging 2018-08-26(9)NMR Relaxation Times of Animal Brains and Protein Models: Implications for Human Brain ULF-MRI 2017-06-12(10)T1 and T2 of Cross-linked Proteins at Ultra-low Field: Implications for Brain ULF-MRI 2016-10-01(11)Magnetic Relaxation Switches to Detect
Protein-Protein Interaction Using Magnetic Nanoparticles at Ultra-low Field 2016-09-05(12)NMR and MRI of Brains and Proteins: SQUID Ultralow Field vs. Conventional High Field 2015-07-06(13)Ultralow Field T1 vs. T1ρ at 3 T & 7 T: Study of Animal Brain Tissues and Rotationally Immobilized Protein Gels 2015-03-04(14)Four-channel ULF-MRI System in Unshielded Urban Laboratory Environment 2014-11-26(15)Ultralow Field Magnetic Resonance Imaging: Eddy Current Cancellation and Tissue Relaxation 2014-11-06(16)Dynamical Cancellation of Eddy Current Transients in an Aluminum Shielded Room: Experimental Demonstration 2014-08-13
指导学生
已指导学生
畅松涛 硕士研究生 080903-微电子学与固体电子学
黄小磊 博士研究生 080903-微电子学与固体电子学
现指导学生
刘少杰 硕士研究生 080903-微电子学与固体电子学
余梦梦 博士研究生 080903-微电子学与固体电子学
肖义 博士研究生 080903-微电子学与固体电子学
尚留洋 硕士研究生 085400-电子信息
徐一力 硕士研究生 085400-电子信息
李永强 博士研究生 080903-微电子学与固体电子学
陶泉 博士研究生 080903-微电子学与固体电子学
王杭 博士研究生 080903-微电子学与固体电子学