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ÄÉÃ×Ïß¾µäÑо¿ÎÄÏ××ÛÊö:Charles Lieber¡¯s Nanowires ½éÉÜÁËCharles LieberµÄ12ƪScienceºÍNatureÑо¿¹¤×÷ ÄÉÃ×Ïß¾µäÑо¿ÎÄÏ××ÛÊö:Charles Lieber¡¯s Nanowires ½éÉÜÁËCharles LieberµÄ12ƪScienceºÍNatureÑо¿¹¤×÷ Reference 1. A. M. Morales, C. M. Lieber, Science 279, 208 (1998). 2. H. Wang, G. S. Fischman, J. Appl. Phys 76 (3), 1557 (1994). 3. X. Duan, C. M. Lieber, J. Am. Chem. Soc., 122, 188 (2000). 4. X. Duan, J. Wang, C. M. Lieber, Appl. Phys. Lett. 76, 1116 (2000). 5. Y. Cui, X. Duan, J. Hu, C. M. Lieber, J. Phys. Chem. B 104, 5213 (2000). 6. X. Duan, C. M. Lieber, Adv. Mater. 12, 298 (2000). 7. J. Hu, M. Ouyang, P. Yang, C. M. Lieber, Nature 399, 48 (1999). 8. M. S. Gudiksen, C. M. Lieber, J. Am. Chem. Soc. 122, 8801 (2000). 9. M. S. Gudiksen, L. J. Lauhon, J. Wang, D. C. Smith, C. M. Lieber, Nature 415, 617 (2002). 10. L. J. Lauhon, M. S. Gudiksen, D. Wang, C. M. Lieber, Nature 420, 57 (2002). 11. W. G. Moffatt, The Handbook of Binary Phase Diagrams (Genium, Schenectady, NY, 1976) 12. Y. Cui, Q. Wei, H. Park, C. M. Lieber, Science 293, 1289 (2001). 13. Y. Huang, X. Duan, Q. Wei, C. M. Lieber, Science 291, 630 (2001). 14. Y. Cui, C. M. Lieber, Science 291, 851 (2001). 15. Y. Huang, X. Duan, Y. Cui, L. J. Lauhon, K. Kim, C. M. Lieber, Science 294, 1313 (2001). 16. Z. Zhong, D. Wang, Y. Cui, M. W. Bockrath, C. M. Lieber, Science 302, 1377 (2003). 17. X. Duan, Y. Huang, Y. Cui, J. Wang, C. M. Lieber, Nature 409, 66 (2001). 18. J. Wang, M. S. Gudiksen, X. Feng, C. M. Lieber, Science 293, 1455 (2001). 19. X. Duan, Y. Huang, R. Agarwal, C. M. Lieber, Nature 421, 241 (2003). 20. D. Wang, F. Qian, C. Yang, Z. Zhong, C. M. Lieber, Nano Lett. 4(5), 871 (2004). http://cmliris.harvard.edu/publications/1998/nature394_52.pdf http://cmliris.harvard.edu/publications/1999/nature399_48.pdf http://cmliris.harvard.edu/publications/2001/science294_1313.pdf http://cmliris.harvard.edu/publications/2001/science293_1289.pdf http://cmliris.harvard.edu/publications/2001/science291_851.pdf http://cmliris.harvard.edu/publications/2001/science291_630.pdf http://cmliris.harvard.edu/publications/2001/nature409_66.pdf http://cmliris.harvard.edu/publications/2001/science293_1455.pdf http://cmliris.harvard.edu/publications/2002/nature415_617.pdf http://cmliris.harvard.edu/publications/2002/nature420_57.pdf http://cmliris.harvard.edu/publications/2003/science302_1377.pdf http://cmliris.harvard.edu/publications/2004/nature430_61.pdf http://cmliris.harvard.edu/publications/2004/nanoLett4_871.pdf http://cmliris.harvard.edu/publications/2000/aPL76_1116.pdf http://cmliris.harvard.edu/publications/2000/advMat12_298.pdf http://cmliris.harvard.edu/publications/2000/jACS122_188.pdf http://cmliris.harvard.edu/publications/2000/jPCB104_5213.pdf http://cmliris.harvard.edu/publications/2000/jACS122_8801.pdf [ Last edited by 604gq on 2007-5-19 at 18:22 ] |
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Functional Nanowires Charles M. Lieber and Zhong Lin Wang, Guest Editors Abstract Nanotechnology offers the promise of enabling revolutionary advances in diverse areas ranging from electronics, optoelectronics, and energy to healthcare. Underpinning the realization of such advances are the nanoscale materials and corresponding nanodevices central to these application areas. Semiconductor nanowires and nanobelts are emerging as one of the most powerful and diverse classes of functional nanomaterials that are having an impact on science and technology. In this issue of MRS Bulletin, several leaders in this vibrant field of research present brief reviews that highlight key aspects of the underlying materials science of nanowires, basic device functions achievable with these materials, and developing applications in electronics and at the interface with biology. This article introduces the controlled synthesis, patterned and designed self-assembly, and unique applications of nanowires in nanoelectronics, nano-optoelectronics, nanosensors, nanobiotechnology, and energy harvesting. http://www.nanoscience.gatech.edu/zlwang/paper/2007/07_MRSB_2.pdf |
2Â¥2007-05-14 21:23:33
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Nanowire - Based Nanoelectronic Devices in the Life Sciences Fernando Patolsky, Brian P. Timko, Gengfeng Zheng, and Charles M. Lieber Abstract The interface between nanosystems and biosystems is emerging as one of the broadest and most dynamic areas of science and technology, bringing together biology, chemistry, physics, biotechnology, medicine, and many areas of engineering. The combination of these diverse areas of research promises to yield revolutionary advances in healthcare, medicine, and the life sciences through the creation of new and powerful tools that enable direct, sensitive, and rapid analysis of biological and chemical species. Devices based on nanowires have emerged as one of the most powerful and general platforms for ultrasensitive, direct electrical detection of biological and chemical species and for building functional interfaces to biological systems, including neurons. Here, we discuss representative ex amples of nanowire nanosensors for ultrasensitive detection of proteins and individual virus par ticles as well as recording, stimulation, and inhibition of neuronal signals in nanowire¨Cneuron hybrid structures. http://cmliris.harvard.edu/publications/2007/MRS......Bull_32_142.pdf |
3Â¥2007-05-14 21:24:59
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Semiconductor nanowires Abstract Semiconductor nanowires (NWs) represent a unique system for exploring phenomena at the nanoscale and are also expected to play a critical role in future electronic and optoelectronic devices. Here we review recent advances in growth, characterization, assembly and integration of chemically synthesized, atomic scale semiconductor NWs. We first introduce a general scheme based on a metal-cluster catalyzed vapour¨Cliquid¨Csolid growth mechanism for the synthesis of a broad range of NWs and nanowire heterostructures with precisely controlled chemical composition and physical dimension. Such controlled growth in turn results in controlled electrical and optical properties. Subsequently, we discuss novel properties associated with these one-dimensional (1D) structures such as discrete 1D subbands formation and Coulomb blockade effects as well as ballistic transport and many-body phenomena. Room-temperature high-performance electrical and optical devices will then be discussed at the single- or few-nanowire level. We will then explore methods to assemble and integrate NWs into large-scale functional circuits and real-world applications, examples including high-performance DC/RF circuits and flexible electronics. Prospects of a fundamentally different ¡®bottom-up¡¯ paradigm, in which functionalities are coded during growth and circuits are formed via self-assembly, will also be briefly discussed. Download link http://cmliris.harvard.edu/publications/2006/JPhysDApplPhys_39_R387.pdf |
4Â¥2007-05-14 21:27:45
5Â¥2007-05-15 12:44:00
7Â¥2007-05-17 11:44:55
8Â¥2007-05-18 22:58:23
9Â¥2007-05-22 09:06:23
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 ¼¸ÆªÔÚË®ÈÜÒºÖкϳÉÄÉÃ×Ïß¡¢°ô¡¢¹ÜµÄÎÄÕÂAqueous Chemical Route to Ferromagnetic 3-D Arrays of Iron Nanorods Lionel Vayssieres,* Lew Rabenberg, and Arumugam Manthiram Texas Materials Institute, UniVersity of Texas at Austin, Austin, Texas 72 ABSTRACT The fabrication of very large arrays of oriented ferromagnetic iron nanorods by aqueous chemical growth without template, surfactant, or applied electric or magnetic field is reported. The method involves the direct growth of â iron oxyhydroxide nanorods from an aqueous ferric chloride solution onto single or polycrystalline substrates, followed by reduction in hydrogen atmosphere at mild temperatures.  Controlled Aqueous Chemical Growth of Oriented Three-Dimensional Crystalline Nanorod Arrays: Application to Iron(III) Oxides Lionel Vayssieres,* Niclas Beermann,Sten-Eric Lindquist, and Anders Hagfeldt Department of Physical Chemistry, University of Uppsala, Box 532, SE-75121 Uppsala, Sweden Purpose-Built Anisotropic Metal Oxide Material: 3D Highly Oriented Microrod Array of ZnO Lionel Vayssieres,* Karin Keis, Sten-Eric Lindquist, and Anders Hagfeldt Abstract We are reporting here on the inexpensive fabrication of large three-dimensional and highly oriented porous microrod array of n-type ZnO semiconductor with a unique designed architecture consisting of well-defined,length-tailored, monodisperse, perpendicularly oriented single-crystalline hexagonal rods, grown directly onto polycrystalline, single-crystalline, or amorphous substrates, from an aqueous solution of zinc salt at low temperature.Highly Ordered SnO2 Nanorod Arrays from Controlled Aqueous Growth** Lionel Vayssieres* and Michael Graetzel Growth of Arrayed Nanorods and Nanowires of ZnO from Aqueous Solutions- Lionel Vayssieres  Three-Dimensional Array of Highly Oriented Crystalline ZnO MicrotubesLionel Vayssieres,* Karin Keis,Anders Hagfeldt, and Sten-Eric Lindquist  http://rapidshare.com/files/33236674/L.vayssieres.rar [ Last edited by zhaokelun1975 on 2007-6-20 at 09:46 ] |
10Â¥2007-06-02 15:50:45
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