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1981Ä꣬ѧʿ£¬Franklin and MarshallѧԺ
1985Ä꣬²©Ê¿£¬Ë¹Ì¹¸£Stanford´óѧ
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1985-87 ¼ÓÖÝÀí¹¤´óѧ£¨CALTECH£©, ²©Ê¿ºó
1987-90 ¸çÂ×±ÈÑÇ´óѧ, Öú½Ì
1990-91 ¸çÂ×±ÈÑÇ´óѧ, ¸±½ÌÊÚ
1991-99 ¹þ·ð´óѧ, ½ÌÊÚ
1999-ÖÁ½ñ ¹þ·ð´óѧ, Mark Hyman Jr.½ÌÊÚ
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Advances in Nanoscale Materials and Nanotechnology
AIP/APS Virtual Journal of Nanoscale Science and Technology
Applied Physics Letters (IF:3.844)
Encyclopedia of Nanoscience and Nanotechnology
Fullerenes, Nanotubes and Carbon Nanostructures
Journal of Applied Physics (IF:2.168)
Journal of Nanoscience and Nanotechnology (IF:1.563)
Journal of Physical Chemistry
Nanotechnology Opportunity Report
Nano Letters (IF:13.198)
¹þ·ð´óѧ»¯Ñ§Ïµ½ÌÊÚCharles M. Lieber (ÖÐÒëÃû£º²é¶û˹-ÁÒ²¨)£¬³¤ÆÚ´ÓÊÂÔ×ÓÁ¦ÏÔ΢¾µ¡¢ËíµÀɨÃèµç¾µ¡¢¸ß㬵¼²ÄÁÏ¡¢ÄÉÃ×µç×Óѧ¡¢ÄÉÃײÄÁϵÄÑо¿£¬ÊÇÄ¿Ç°¹ú¼ÊÉÏ×îȨÍþ¡¢×î»îÔ¾¡¢×îÖøÃû¡¢ÄêÇáÓÐΪµÄÄÉÃ׿Æѧ¼ÒºÍ²ÄÁÏѧ¼ÒÖ®Ò»£¬¶Ô¹ú¼ÊÄÉÃ׿Ƽ¼µÄ·¢Õ¹×ö³öÁËÖØ´ó¹±Ï×£¬ÔÚ¹ú¼ÊÉÏÏíÓÐÊ¢Óþ£¬¾ßÓм«¸ßµÄÔìÒè¡£ÔÚÄÉÃ׿Ƽ¼Ñо¿ÁìÓòÖУ¬¿ÉÒÔ˵ûÓÐÈ˲»ÖªµÀËûµÄÃû×Ö»òËûµÄÑо¿¹¤×÷¡£²é¶û˹-ÁÒ²¨½ÌÊÚÕæ¿ÉνÊÇÎÞÈ˲»Öª¡¢ÎÞÈ˲»ÏþµÄ¹ú¼Ê¶¥¼âµÄÄÉÃ׿Æѧ¼ÒÖ®Ò»¡£ËûµÄÑо¿¹¤×÷Õ¾ÔÚѧÊõ×îÇ°ÑØ£¬Áìµ¼×ÅÄÉÃ׿Æѧ¼¼Êõ·¢Õ¹µÄ³±Á÷¡£ÒÔ2001ÄêΪÀý£¬Ò»ÄêÄÚËûÁìµ¼µÄ¿ÆÑÐС×é¾ÍÔÚScience¡¢Nature¿¯ÎïÉÏ·¢±íÂÛÎÄ10ƪ¡£²é¶û˹-ÁÒ²¨½ÌÊÚÔÚÄÉÃ׿ÆѧºÍ¼¼ÊõÑо¿ÁìÓòÔø×ö³ö¹ýһϵÁÐÖØ´ó¹±Ï×£¬ËûÔø·¢Ã÷ÁËÄÉÃ×Ä÷×ÓµÈÄÉÃ×¹¤¾ß¡¢P-NÄÉÃ׶þ¼«¹ÜµÈ£»×î½ü¸üÊÇ»îÔ¾ÔÚÄÉÃ×̼¹Ü¡¢ÄÉÃ×ÏßµÄÑо¿ÁìÓò£¬È¥ÄêËûµÄÑо¿³É¹û±»ÃÀ¹ú¿Æ¼¼ÐÂÎÅÆÀѡΪ¹ú¼ÊÊ®´ó¿ÆѧÖØ´ó½øÕ¹Ö®Ò»¡£¼øÓÚ²é¶û˹oÁÒ²¨½ÌÊÚµÄ׿Խ¹±Ï×£¬Ëû»ñµÃÁË´óÁ¿½±Àø¡£ÖµµÃÒ»ÌáµÄÊÇ£¬ËûÔø»ñµÃÄÉÃ×¼¼ÊõÁìÓò×î¸ß´ó½±-¡°·ÑÂü½±¡°¡¢¹ú¼Ê²ÄÁÏѧ»á¡°½Ü³öÇàÄê½±¡°¡¢ÃÀ¹ú¡°×Üͳ½±¡°¡¢ÃÀ¹ú»¯Ñ§»á¡°´¿»¯Ñ§½±¡°¡¢ÃÀ¹ú¿Æѧ»ù½ð»á¡°´´Ôì½±¡°µÈµÈ¡£ËûÔÚ¸÷ÖÖÖØÒª´óÐ͹ú¼Ê»áÒéºÍÃÀ¹ú»¯Ñ§»á»áÒéÉÏËù×öµÄÌØÑû´ó»á±¨¸æ¾Í´ï40´ÎÖ®¶à¡£½üÄêÀ´£¬²é¶û˹-ÁÒ²¨½ÌÊÚ½ÌÊÚÏȺ󷢱íѧÊõÂÛÎÄ200Óàƪ£¬ÆäÖаüÀ¨ÔÚ¹ú¼Ê×îȨÍþ¿¯ÎïNature¡¢ScienceÉÏ·¢±íµÄÂÛÎÄ41ƪ£¬ÔÚ»¯Ñ§½ç¡¢ÎïÀí½ç×î¸ßѧÊõ¿¯ÎïJ. Am. Chem. Soc.£¬Phys. Rew. Lett.ÉÏ·¢±íÂÛÎÄ´ï40ƪ¡£
²é¶û˹-ÁÒ²¨½ÌÊÚÔçÄê´ÓʱíÃæÎïÀí»¯Ñ§Ñо¿£¬Ôø½¨Á¢Á˵ç×ÓɨÃèËíµÀ£¨STM£©µÄ±íÃæµç×Ó̽Õë½á¹¹ÀíÂÛ£¬µì¶¨ÁËSTMµÄ»ù´¡£¬ÎªSTMµÄ·¢Õ¹×ö³öÁËÖØÒª¹±Ïס£Îª´Ë£¬¹þ·ð´óѧֱ½ÓƸËûΪÕý½ÌÊÚ£¬ÏÖÔÚËûÒѳÉΪ¹þ·ð´óѧ×î¸ßÖÕÉíÂí¿Ë-ºÚÂü£¨Mark Hyman£©½ÌÊÚ£¬ÊǼ«ÓÐÏ£Íû»ñµÃŵ±´¶û½±µÄ¹ú¼ÊÖøÃû½ÌÊÚÖ®Ò»¡£
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2000¡¡¹ú¼ÊÁªºÏ´¿´âÓ¦Óû¯Ñ§»áÑо¿Ô±
1997¡¡ÃÀ¹úÏȽø¿ÆѧлáÑо¿Ô±
1996 ÃÀ¹úÎïÀí»áÑо¿Ô±
1996 ÃÀ¹ú¿Æѧ»ù½ð´´Ôì½±
1995¡¡ÃÀ¹ú»¯Ñ§»áLeo Hendrik Baekeland½±£¨²ÄÁÏ»¯Ñ§×î¸ß½±Ï
1994£1995¡¡¹þ·ð´óѧGeorge Ledlie½±
1994 Ó¢¹ú¸çÂ×±ÈÑÇ´óѧ²ÄÁÏ¿Æѧ3MÑݽ²½±
1994 ¸»À¼¿ËÁÖMarshallѧԺMerck½²Ê¦½±
1993 ²ÄÁÏÑо¿Ñ§»á½Ü³öÇàÄêÑо¿½±
1992 ÃÀ¹ú»¯Ñ§»á´¿´â»¯Ñ§½±
1992¡¡ Dinkewalter½±
1990£1995¡¡ Camille ºÍ Henry Dreyfus½ÌʦѧÕß½±
1990¡¡Íþ¶ûÑ·£¨Wilson£©½±
1990£1992¡¡ ˹¡£¨Alfred P. Sloan£©Ñо¿Ô±
1988£1993¡¡ DavidºÍLucile PackardÑо¿Ô±
1988£1993¡¡ÏȽøÇàÄêÑо¿½±
1987¡¡Dreyfus »ù½ð½Ü³ö²ÅÄܽ±
1985£1987¡¡NIH²©Ê¿ºóÑо¿»á³ÉÔ±
1985 Joseph W. Richardsµç»¯Ñ§»á³ÉÔ±
1981 B. A. ѧ룬Magna Cum Laude»¯Ñ§ÈÙÓþ
1981 ÃÀ¹ú»¯Ñ§¼Òлá½Ü³ö×ʸñ½±
1981 Theodore SaulnierÑо¿½±
1981¡¡ ׿Խ»¯Ñ§¹±Ï×Pentathalon ½±ÕÂ
1981 ±»Ñ¡ÎªPhi Beta Kappa »¯Ñ§½±
¹²·¢±íÂÛÎÄ200Óàƪ¡£Ôø±»ÑûÇëÔÚ¸÷ÖÖÖØÒª¹ú¼ÊѧÊõ»áÒéºÍÃÀ¹ú»¯Ñ§»á¡¢ÎïÀíѧ»á¡¢²ÄÁÏѧ»á×ö´ó»áÑûÇ뱨¸æ´ï40´Î¡£¶à´ÎÔÚAcc. Chem. Res., Am. Sci. µÈ¹ú¼ÊÖøÃû¿¯ÎïÉÏ׫д×ÛÊöÐÔÂÛÎÄ10ƪÒÔÉÏ£¬ÂÛÎı»ÒýÓÃ7000´ÎÒÔÉÏ¡£
Charles M. Lieber ½ÌÊÚ·¢±íµÄ´ú±íÐÔÂÛÎÄ£º (ÕâЩÎÄ×ֱȽϹÅÀÏ,Õª¼¸Æª¼´¿É)
1. C. M. Lieber and N. S. Lewis, ¡°Catalytic Reduction of CO2 at Carbon Electrodes Modified with Cobalt Phthalocyanine¡°. J. Am. Chem. Soc. 106, 5033 (1984).
2. C. M. Lieber, C. M. Gronet and N. S. Lewis, ¡°Evidence Against Surface State Limitations on the Efficiency of p-Si/CH3CN Junctions¡°. Nature 307, 533 (1984).
3. C. M. Lieber and N. S. Lewis, ¡°Probing Polymer Effects on Chemical Reactivity: Ligand Substitution Kinetics of Ru(NH3)5(H2O)2+ in Nafion Films¡°. J. Am. Chem. Soc. 107, 7190 (1985).
4. C. M. Lieber, M. Schmidt, and N. S. Lewis, ¡°Kinetic Studies of Ligand Substitution Rates for the Ru(NH3)5(H2O)2+ ion in Nafion Films¡°. J. Am. Chem. Soc. 108, 6103 (1986).
5. C. M. Lieber, J. L. Karas, and H. B. Gray, ¡°Reversible Long-Range Electron Transfer in Ruthenium-Modified Sperm Whale Myoglobin¡°. J. Am. Chem. Soc. 109, 3778 (1987).
6. J. L. Karas, C. M. Lieber, and H. B. Gray, ¡°Free Energy Dependence of the Rate of Long-Range Electron Transfer in Proteins. Experimental Execuation of the Reorganization Energy in Ruthenium-Modified Myoglobin¡°. J. Am. Chem. Soc. 110, 599 (1988).
7. X. L. Wu and C. M. Lieber, ¡°Determination of the Structural and Electronic Properties of Surfaces using Scanning Tunneling Microscopy Coupled with Chemical Modifications¡° J. Am. Chem. Soc. 110, 5200 (1988).
8. X. L. Wu, P. Zhou and C. M. Lieber, ¡°Surface Electronic Properties Probed with Tunneling Microscopy and Chemical Doping¡°. Nature 335, 55 (1988).
9. X. L. Wu, P. Zhou and C. M. Lieber, ¡°Determination of the Local Effect of Impurities on the Charge Density Wave Phase in TaS2 by Scanning Tunneling Microscopy¡° Phys. Rev. Lett. 61, 2604 (1988).
10. X. L. Wu and C. M. Lieber, ¡°The Hexagonal Domain-Like Charge Density Wave Phase of TaS2 Determined by Scanning Tunneling Microscopy¡°. Science 243, 1703 (1989).
11. X. L. Wu and C. M. Lieber, ¡°Scanning Tunneling Investigations Investigations of a New Charge Density Wave Phase in Niobium-Doped Tantalum Disulfide¡°. J. Am. Chem. Soc. 111, 2731 (1989)
Nanobeam Mechanics: Elasticity, Strength, and Toughness of Nanorods and Nanotubes (Citations: 724)
Eric W. Wong, Paul E. Sheehan, Charles M. Lieber
Journal: Science , vol. 277, no. 5334, pp. 1971-1975, 1997
Nanowire Nanosensors for Highly Sensitive and Selective Detection of Biological and Chemical Species (Citations: 675)
Yi Cui, Qingqiao Wei, Hongkun Park, Charles M. Lieber
Journal: Science , vol. 293, no. 5533, pp. 1289-1292, 2001
A Laser Ablation Method for the Synthesis of Crystalline Semiconductor Nanowires (Citations: 521)
Alfredo M. Morales, Charles M. Lieber
Journal: Science , vol. 279, no. 5348, pp. 208-211, 1998
Functional Nanoscale Electronic Devices Assembled Using Silicon Nanowire Building Blocks (Citations: 439)
Y. Cui, C. Lieber
Journal: Science , vol. 291, no. 5505, pp. 851-853, 2001
Logic Gates and Computation from Assembled Nanowire Building Blocks (Citations: 419)
Yu Huang, Xiangfeng Duan, Yi Cui, Lincoln J. Lauhon, Kyoung-Ha Kim, Charles M. Lieber
Journal: Science , vol. 294, no. 5545, pp. 1313-1317, 2001
Carbon Nanotube-Based Nonvolatile Random Access Memory for Molecular Computing (Citations: 366)
Thomas Rueckes, Kyoungha Kim, Ernesto Joselevich, Greg Y. Tseng, Chin-Li Cheung, Charles M. Lieber
Journal: Science , vol. 289, no. 5476, pp. 94-97, 2000
Growth of nanowire superlattice structures for nanoscale photonics and electronics (Citations: 296)
Mark S. Gudiksen, Lincoln J. Lauhon, Jianfang Wang, David C. Smith, Charles M. Lieber
Journal: Nature , vol. 415, no. 6872, pp. 617-620, 2002
Multiplexed electrical detection of cancer markers with nanowire sensor arrays (Citations: 277)
Journal: Nature Biotechnology - NAT BIOTECHNOL , vol. 23, no. 10, pp. 1294-1301, 2005
Single-nanowire electrically driven lasers (Citations: 237)
Xiangfeng Duan, Yu Huang, Ritesh Agarwal, Charles M. Lieber
Journal: Nature , vol. 421, no. 6920, pp. 241-245, 2003
Epitaxial core¨Cshell and core¨Cmultishell nanowire heterostructures (Citations: 228)
Lincoln J. Lauhon, Mark S. Gudiksen, Deli Wang, Charles M. Lieber
Journal: Nature , vol. 420, no. 6911, pp. 57-61, 2002
Observation of metastable A¦Â amyloid protofibrils by atomic force microscopy (Citations: 189)
James D. Harper, Stanislaus S. Wong, Charles M. Lieber, Peter T. Lansbury
Journal: Chemistry & Biology - CHEM BIOL , vol. 4, no. 2, pp. 119-125, 1997
Coaxial silicon nanowires as solar cells and nanoelectronic power sources (Citations: 179)
Bozhi Tian, Xiaolin Zheng, Thomas J. Kempa, Ying Fang, Nanfang Yu, Guihua Yu, Jinlin Huang, Charles M. Lieber
Journal: Nature , vol. 449, no. 7164, pp. 885-889, 2007
General Synthesis of Compound Semiconductor Nanowires (Citations: 177)
X. Duan, C. M. Lieber
Journal: Advanced Materials - ADVAN MATER , vol. 12, no. 4, pp. 298-302, 2000
Diameter-controlled synthesis of single crystal silicon nanowires (Citations: 164)
Y. Cui, L. J. Lauhon, M. S. Gudiksen, J. Wang, C. M. Lieber
Published in 2001.
Direct Ultrasensitive Electrical Detection of DNA and DNA Sequence Variations Using Nanowire Nanosensors (Citations: 159)
Jong-in Hahm, Charles M. Lieber
Journal: Nano Letters - NANO LETT , 2004
Ge/Si nanowire heterostructures as high-performance field-effect transistors (Citations: 157)
Jie Xiang, Wei Lu, Yongjie Hu, Yue Wu, Hao Yan, Charles M. Lieber
Journal: Nature , vol. 441, no. 7092, pp. 489-493, 2006
Highly Polarized Photoluminescence and Photodetection from Single Indium Phosphide Nanowires (Citations: 157)
.Journal: Science , vol. 293, no. 5534, pp. 1455-1457, 2001
Indium phosphide nanowires as building blocks for nanoscale electronic and optoelectronic devices (Citations: 156)
Xiangfeng Duan, Yu Huang, Yi Cui, Jianfang Wang, Charles M. Lieber
Journal: Nature
Electrical detection of single viruses (Citations: 156)
Fernando Patolsky, Gengfeng Zheng, Oliver Hayden, Melike Lakadamyali, Xiaowei Zhuang, Charles M. Lieber
catalysts, silane as reactant, and diborane as p-type dopant with aB Si ratio of 1:4,000. Arrays of silicon nanowire devices were defined by using photolithography with Ni metal contacts (14) on silicon substrates with a 600-nm-thick oxide layer. The metal contacts to the nanowires were isolated by subsequent deposi- tion of 50-nm-thick Si3N4 ...
Journal: Proceedings of The National Academy of Sciences - PNAS , vol. 101, no. 39, pp. 14017-14022, 2004
Atomic structure and electronic properties of single walled carbon nanotubes (Citations: 149)
T. W. Odom, J. L. Huang, P. Kim, C. M. Lieber
Journal: Nature , 1998
Probing Electrical Transport in Nanomaterials: Conductivity of Individual Carbon Nanotubes (Citations: 147)
H. Dai, E. W. Wong, C. M. Lieber
Journal: Science , vol. 272, no. 5261, pp. 523-526, 1996
Functional Group Imaging by Chemical Force Microscopy (Citations: 142)
C. Daniel Frisbie, Lawrence F. Rozsnyai, Aleksandr. Noy, Mark S. Wrighton, Charles M. Lieber
Journal: Science , vol. 265, no. 5181, pp. 2071-2074, 1994
Synthesis and characterization of carbide nanorods (Citations: 129)
Hongjie Dai, Eric W. Wong, Yuan Z. Lu, Shoushan Fan, Charles M. Lieber
Journal: Nature , vol. 375, no. 6534, pp. 769-772, 1995
Nanowire Crossbar Arrays as Address Decoders for Integrated Nanosystems (Citations: 123)
Z. Zhong, D. Wang, Y. Cui, M. W. Bockrath, C. M. Lieber
Journal: Science , vol. 302, no. 5649, pp. 1377-1379, 2003
Single-crystal metallic nanowires and metal/semiconductor nanowire heterostructures (Citations: 117)
Yue Wu, Jie Xiang, Chen Yang, Charles M. Lieber
Journal: Nature , vol. 430, no. 6995, pp. 61-65, 2004
Directed assembly of one-dimensional nanostructures into functional networks (Citations: 108)
Y. Huang, X. Duan, Q. Wei, C. M. Lieber
Journal: Science , 2003
Atomic force microscopic imaging of seeded fibril formation and fibril branching by the Alzheimer's disease amyloid-¦Â protein (Citations: 102)
James D. Harper, Charles M. Lieber, Peter T. Lansbury Jr
Background: Amyloid plaques composed of the fibrillar form of the amyloid-¦Â protein (A¦Â) are the defining neuropathological feature of Alzheimer's disease (AD). A detailed understanding of the time course of amyloid formation could define steps in disease progression and provide targets for therapeutic intervention. Amyloid fibrils, indistinguishable from those derived from an AD brain, can be produced in ...
Journal: Chemistry & Biology - CHEM BIOL , vol. 4, no. 12, pp. 951-959, 1997
Nanowire electronic and optoelectronic devices (Citations: 100)
Yat Li, Fang Qian, Jie Xiang, Charles M. Lieber
Journal: Materials Today - MATER TODAY , vol. 9, no. 10, pp. 18-27, 2006
Covalently functionalized nanotubes as nanometresizedprobes in chemistry and biology (Citations: 93)
S. S. Wong, E. Joselevich, A. T. Woolley, C. L Cheung, C. M. Lieber
Journal: Nature , 1998
Directed assembley of one-dimensional nanostructures into functional networks (Citations: 83)
Y. Huang, X. Duan, Q. Wei, C. M. Lieber
Journal: Science , 2001
Nanowire nanosensors (Citations: 71)
Fernando Patolsky, Charles M. Lieber
Journal: Materials Today - MATER TODAY , vol. 8, no. 4, pp. 20-28, 2005
Experimental Realization of the Covalent Solid Carbon Nitride (Citations: 68)
C. Niu, Y. Z. Lu, C. M. Lieber
Journal: Science , vol. 261, no. 5119, pp. 334-337, 1993
Fabrication of silicon nanowire devices for ultrasensitive, label-free, real-time detection of biological and chemical species (Citations: 68) |
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