| Notes |
1
Charles M. Lieber
Department of Chemistry and Chemical Biology
Harvard John A. Paulson School of Engineering and Applied Sciences
Harvard University
12 Oxford Street, Cambridge, MA 02138
Personal Data
Date and Place of Birth: 9 April 1959; Philadelphia, PA
Academic Training
Undergraduate: B.A. in Chemistry, Franklin and Marshall College, 1981
Graduate: Ph.D. in Chemistry, Stanford University, 1985
Postgraduate: Postdoctoral Research, California Institute of Technology, 1985-1987
Professional Experience
1987-1990: Assistant Professor of Chemistry, Columbia University
1990-1991: Associate Professor of Chemistry, Columbia University
1991-1999: Professor of Chemistry, Harvard University
1999-2017: Mark Hyman Professor of Chemistry, Harvard University
2015-present: Chair, Department of Chemistry and Chemical Biology, Harvard University
2017-present: Joshua and Beth Friedman University Professor, Harvard University
Academic and Professional Awards
Welch Award in Chemistry (2019); John Gamble Kirkwood Award, Yale University (2018); Director’s
Pioneer Award, National Institutes of Health (2017 & 2008); MRS Von Hippel Award (2016); Remsen
Award (2016); Nano Research Award, Tsinghua University Press/Springer (2013); IEEE
Nanotechnology Pioneer Award (2013); Willard Gibbs Medal (2013); Wolf Prize in Chemistry (2012);
Fred Kavli Distinguished Lectureship in Nanoscience, Materials Research Society (2010); Friendship
Award, People’s Republic of China (2009); Inorganic Nanoscience Award, ACS Division of Inorganic
Chemistry (2009); Einstein Award, Chinese Academy of Sciences (2008); NBIC Research Excellence
Award, University of Pennsylvania (2007); Nanotech Briefs Nano 50 Award (2005); World Technology
Award in Materials (2004 & 2003); ACS Award in the Chemistry of Materials (2004); Scientific
American 50 Award in Nanotechnology and Molecular Electronics (2003); Nelson W. Taylor Award,
Pennsylvania State University (2003); New York Intellectual Property Law Association Inventor of the
Year Award (2003); APS McGroddy Prize for New Materials (2003); Harrison Howe Award, University
of Rochester (2002); MRS Medal (2002); Foresight Institute Feynman Prize in Nanotechnology (2001);
NSF Creativity Award (1996); Leo Hendrik Baekeland Award, American Chemical Society (1995);
George Ledlie Prize, Harvard University (1994-1995); MRS Outstanding Young Investigator Award
(1993); ACS Award in Pure Chemistry (1992); Denkewalter Prize, Loyola University Chicago (1992);
Camille and Henry Dreyfus Teacher-Scholar Award (1990-1995); Alfred P. Sloan Research Fellowship
(1990-1992); Wilson Prize (1990); NSF Presidential Young Investigator Award (1988-1993); David and
Lucile Packard Fellowship (1988-1993); Distinguished New Faculty Award, Dreyfus Foundation
(1987); NIH Postdoctoral Research Fellow (1985-1987); Joseph W. Richards Fellow of the
Electrochemical Society (1985); American Institute of Chemists Distinguished Senior Award (1981);
Theodore Saulnier Research Award (1981); Pentathlon Medal for Excellence in Chemistry (1981).
2
Honorary Degrees
Doctor of Science, University of Chicago (2018); Doctor of Science, Honoris Causa, Franklin &
Marshall College (2018); Doctor of Science, Union College (2018).
Elected Memberships and Fellowships
Elected Member, National Academy of Medicine (2017); Elected Foreign Member, Chinese Academy
of Science (2015); Elected Member, National Academy of Inventors (2013); Fellow, American
Chemical Society, Inaugural Class (2009); Honorary Fellow, Chinese Chemical Society (2009); Elected
Fellow, Materials Research Society (2008); Elected Fellow, Institute of Physics (2004); Elected
Member, National Academy of Sciences (2004); Elected Fellow, American Academy of Arts and
Sciences (2002); Elected Fellow, World Technology Network (2002); Elected Fellow, International
Union of Pure and Applied Chemistry (2000); Elected Fellow, American Association for the
Advancement of Science (1996); Elected Fellow, American Physical Society (1996).
Honorary Professorships
Nankai University (2014); Institute of Chemistry, Chinese Academy of Sciences (2014); University of
Science and Technology Beijing (2011); Peking University (2008); Tsinghua University (2002);
University of Science and Technology of China (2002); Fudan University (2002); Zhejiang University
(2002).
Professional Society Memberships
American Association for the Advancement of Science, American Chemical Society, American Physical
Society, Institute of Electrical and Electronics Engineers, International Society for Optical Engineering,
Materials Research Society, Optical Society of America, Society for Neuroscience.
Scientific Advisory Boards
International Advisory Board, National Center for Nanoscience and Technology, China; International
Board, Weizmann Institute of Science; Scientific and Academic Advisory Committee, Weizmann
Institute of Science.
Editorial Advisory Boards
Nano Letters (Co-Editor); Chinese Journal of Chemistry; E-Journal of Surface Science and
Nanotechnology; Engineering; Frontier of Neuroscience, Neural Nanotechnology section; International
Journal of Biomedical Nanoscience and Nanotechnology; Journal of Computational and Theoretical
Nanoscience; International Journal of Molecular Sciences, Molecular Diagnostics Section; Journal of
Nanoscience and Nanotechnology; Nano Energy; Nano Research and Nano Today; Nanoscience.
Research Interests
Chemistry and physics of materials with an emphasis on rational synthesis, hierarchical assembly and
fundamental physical properties of nanoscale wires; nano-bioelectronics with a focus on real-time, ultrasensitive detectors, revolutionary tools for single cell measurements, and three-dimensional innervation
of synthetic tissue and organs; brain science with an emphasis on development of the new syringeinjectable electronics paradigm for long-term mapping and modulation of neural activity in live animals,
studies of fundamental problems in neuroscience, including memory, learning and cognition, and the
development of implants for the treatment of disease.
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Publications
Lieber has published over 400 articles in peer-reviewed scientific journals. His original work has had a
defining influence on the field of nanoscience and nanotechnology, where his publications have been
cited overall more than 106,800 times, his top 10 papers have been cited more than 29,500 times, and his
h-index (impact factor) is 144. Based on his citation impact scores, Lieber was ranked #1 in Chemistry
for the decade 2000-2010 by Thomson Reuters. Publications are as follows:
1. C.M. Lieber, C.M. Gronet and N.S. Lewis, “Evidence against surface state limitations on
efficiency of p-Si/CH3CN junctions,” Nature 307, 533-534 (1984).
2. M.L. Rosenbluth, C.M. Lieber and N.S. Lewis, “630-mV open circuit voltage, 12% efficient n-Si
liquid junction,” Appl. Phys. Lett. 45, 423-425 (1984).
3. C.M. Lieber and N.S. Lewis, “Catalytic reduction of CO2 at carbon electrodes modified with
cobalt phthalocyanine,” J. Am. Chem. Soc. 106, 5033-5034 (1984).
4. N.S. Lewis, R. Domingues, C.M. Gronet, C.M. Lieber, M.D. Rosenblum, G.W. Cogan, J.F.
Gibbons and G.R. Moddel, “Design of efficient semiconductor/liquid junction interfaces in
nonaqueous solvents,” in The Chemistry and Physics of Electrocatalysis (eds. J.D.E. McIntyre et
al.). The Electrochemical Society: Princeton, 1984).
5. 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, 7190-7191
(1985).
6. C.M. Lieber, M.H. Schmidt and N.S. Lewis, “Reaction entropy measurements for transitionmetal ions bound to Nafion-coated electrode surfaces,” J. Phys. Chem. 90, 1002-1003 (1986).
7. C.M. Lieber, M.H. 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, 6103-6108 (1986).
8. C.M. Lieber, “Probing polymer induced reactivity effects in modified electrode catalyst
systems,” J. Electrochem. Soc. 133, 442C-444C (1986).
9. C.M. Lieber, J.L. Karas and H.B. Gray, “Reversible long-range electron transfer in rutheniummodified sperm whale myoglobin,” J. Am. Chem. Soc. 109, 3778-3779 (1987).
10. J.L. Karas, C.M. Lieber and H.B. Gray, “Free energy dependence of the rate of long-range
electron transfer in proteins. Reorganization energy in ruthenium-modified myoglobin,” J. Am.
Chem. Soc. 110, 599-600 (1988).
11. C.M. Lieber, J.L. Karas, S.L. Mayo, A.W. Axup, M. Albin, R.J. Crutchley, W.R. Ellis and H.B.
Gray, “Long-range electron transfer in ruthenium-modified metalloproteins,” Trace Elements in
Man and Animals 6 (eds. L.S. Hurley and C.L. Keen), Plenum Press: New York, 1988.
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12. C.M. Lieber, J.L. Karas, S.L. Mayo, M. Albin and H.B. Gray, “Long-range electron transfer in
proteins,” in Proceedings of the Robert A. Welch Foundation Conference on Chemical Research
XXXI, 9-26. Welch Foundation: Houston, 1988.
13. X.-L. Wu and C.M. Lieber, “Determination of the structural and the electronic properties of
surfaces using scanning tunneling microscopy coupled with chemical modifications,” J. Am.
Chem. Soc. 110, 5200-5201 (1988).
14. X.L. Wu, P. Zhou and C.M. Lieber, “Surface electronic properties probed with tunneling
microscopy and chemical doping,” Nature 335, 55-57 (1988).
15. X.-L. Wu and C.M. Lieber, “In situ imaging of a detergent monolayer using scanning tunneling
microscopy,” J. Phys. Chem. 92, 5556-5557 (1988).
16. 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,
2604-2607 (1988).
17. X.L. Wu and C.M. Lieber, “Hexagonal domain-like charge density wave phase of TaS2
determined by scanning tunneling microscopy,” Science 243, 1703-1705 (1989).
18. X.L. Wu and C.M. Lieber, “Scanning tunneling microscopy investigations of a new charge
density wave phase in niobium-doped tantalum disulfide,” J. Am. Chem. Soc. 111, 2731-2733
(1989).
19. S.P. Kelty and C.M. Lieber, “Scanning tunneling microscopy investigations of the electronic
structure of potassium-graphite intercalation compounds,” J. Phys. Chem. 93, 5983-5985 (1989).
20. S.P. Kelty and C.M. Lieber, “Atomic-resolution scanning-tunneling-microscopy investigations
of alkali-metal-graphite intercalation compounds,” Phys. Rev. B 40, 5856-5859 (1989).
21. Y. Kim and C.M. Lieber, “Synthesis and characterization of new binuclear electron-transfer
models containing rigid aromatic spacers,” Inorg. Chem. 28, 3990-3992 (1989).
22. X.L. Wu, C.M. Lieber, D.S. Ginley and R.J. Baughman, “Scanning tunneling microscopy
investigations of the local structure of Tl2Ba2CaCu2O8 single crystals,” Appl. Phys. Lett. 55,
2129-2131 (1989).
23. X.L. Wu and C.M. Lieber, “Direct characterization of charge-density-wave defects in titaniumdoped TaSe2 by scanning tunneling microscopy,” Phys. Rev. B 41, 1239-1242 (1990).
24. X.L. Wu and C.M. Lieber, “Direct observation of growth and melting of the hexagonal-domain
charge-density-wave phase in 1T-TaS2 by scanning tunneling microscopy,” Phys. Rev. Lett. 64,
1150-1153 (1990).
25. H. Chen, X.L. Wu and C.M. Lieber, “Scanning tunneling microscopy investigations of the local
electronic and structural effects of iron substitution in tantalum disulfide,” J. Am. Chem. Soc.
112, 3326-3332 (1990).
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26. X.L. Wu, Z. Zhang, Y.L. Wang and C.M. Lieber, “Structural and electronic role of lead in
(PbBi)2 Sr2CaCu2O8 superconductors by STM,” Science 248, 1211-1214 (1990).
27. Z. Zhang, Y.L. Wang, X.L. Wu, J.-L. Huang and C.M. Lieber, “Electronic effect of lead
substitution in single-crystal Bi(Pb)-Sr-Ca-Cu-O superconductors determined by scanning
tunneling microscopy,” Phys. Rev. B 42, 1082-1085 (1990).
28. Y.L. Wang, X.L. Wu, C.C. Chen and C.M. Lieber, “Enhancement of the critical current density
in single-crystal Bi2Sr2CaCu2O8 superconductors by chemically induced disorder,” Proc. Natl.
Acad. Sci. USA 87, 7058-7060 (1990).
29. Y. Kim and C.M. Lieber, “Chemically etched silicon surfaces viewed at the atomic level by
force microscopy,” J. Am. Chem. Soc. 113, 2333-2335 (1991).
30. X.L. Wu, Y.L. Wang, Z. Zhang and C.M. Lieber, “Electronic and structural effects of oxygen
doping in Bi2Sr2CaCu2Ox superconductors characterized by tunneling microscopy,” Phys. Rev. B
43, 8729-8732 (1991).
31. X.L. Wu and C.M. Lieber, “Applications of scanning tunneling microscopy to inorganic
chemistry,” Prog. Inorg. Chem. 39, 431 (1991).
32. S.P. Kelty and C.M. Lieber, “Scanning tunneling microscopy investigations of the surface
structure and electronic properties of ternary graphite intercalation compounds,” J. Vac. Sci.
Technol. B 9, 1068-1071 (1991).
33. X.L. Wu and C.M. Lieber, “Variable-temperature scanning tunneling microscopy studies of the
charge density wave phases in tantalum disulfide,” J. Vac. Sci. Technol. B 9, 1044 (1991).
34. Z. Zhang and C.M. Lieber, “Scanning tunneling microscopy and spectroscopy studies of the
surface structure and electronic properties of single crystal Tl-Ba-Ca-Cu-O superconductors,” J.
Vac. Sci. & Technol. B 9, 1009 (1991).
35. Z. Zhang, Y.L. Wang, X.L. Wu, J.L. Huang and C.M. Lieber, “The effects of oxygen doping on
the electronic properties and microstructure of Bi2Sr2CaCu2Ox superconductors determined by
scanning tunneling microscopy,” 2nd World Congress on Superconductivity (World Scientific,
Teaneck, 1991).
36. H. Dai, H. Chen and C.M. Lieber, “Weak pinning and hexatic order in a doped two-dimensional
charge-density-wave system,” Phys. Rev. Lett. 66, 3183-3186 (1991).
37. S.P. Kelty, C.C. Chen and C.M. Lieber, “Superconductivity at 30 K in caesium-doped C60,”
Nature 352, 223 (1991).
38. C.C. Chen, S.P. Kelty and C.M. Lieber, “(RbxK1-x)C60 Superconductors: formation of a
continuous series of solid solutions,” Science 253, 886 (1991).
39. C.M. Lieber and X.L. Wu, “Scanning tunneling microscopy studies of low-dimensional
materials: probing the effects of chemical substitutions at the atomic level,” Acc. Chem. Res. 24,
170 (1991).
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40. S.P. Kelty, Z. Lu and C.M. Lieber, “Scanning-tunneling-microscopy investigations of ternary
graphite intercalation compounds,” Phys. Rev. B 44, 4064-4067 (1991).
41. Y. Kim and C.M. Lieber, “Scanning tunneling microscopy imaging of synthetic oligonucleotides
and oligonucleotide-metal complexes,” Scanning Micros. 5, 311-316 (1991).
42. S.P. Kelty, Z. Lu and C.M. Lieber, “Core-level binding energies of Cs-doped C60 and graphite,”
J. Phys. Chem. 95, 6754-6756 (1991).
43. Z. Zhang, C.C. Chen, S.P. Kelty, H. Dai and C.M. Lieber, “The superconducting energy gap of
Rb3C60,” Nature 353, 333 (1991).
44. Z. Zhang, C.-C. Chen and C.M. Lieber, “Tunneling spectroscopy of M3C60 superconductors: The
energy gap, strong coupling, and superconductivity,” Science 254, 1619-1621 (1991).
45. C.M. Lieber and Y. Kim, “Characterization of the structural, electronic, and tribological
properties of metal dichalcogenides by scanning probe microscopies,” Thin Solid Films 206, 355
(1991).
46. Z. Zhang and C.M. Lieber, “The energy gap of the M3C60 superconductors,” Mod. Phys. Lett. B
5, 1905 (1991).
47. Y. Kim, J.-L. Huang and C.M. Lieber, “Characterization of nanometer scale wear and oxidation
of transition metal dichalcogenide lubricants by atomic force microscopy,” Appl. Phys. Lett. 59,
3404-3406 (1991).
48. Z. Zhang and C.M. Lieber, “Determination of the local structure and electronic states of high-Tc
superconductors by scanning tunneling microscopy,” J. Phys. Chem. 96, 2030-2038 (1992).
49. Y. Kim, E.C. Long, J. K. Barton and C.M. Lieber, “Imaging of oligonucleotide-metal complexes
by scanning tunneling microscopy,” Langmuir 8, 496 (1992).
50. Z. Zhang, C.-C. Chen, C.M. Lieber, B. Morosin, D.S. Ginley and E.L. Venturini, “Relationship
between crystal chemistry and the local structure and electronic properties of Tl2Ba2Ca2Cu3O10
superconductors determined by scanning tunneling microscopy and spectroscopy,” Phys. Rev. B
45, 987-992 (1992).
51. S.P. Kelty and C.M. Lieber, “Scanning tunneling microscopy investigations of graphite
intercalation compounds,” CRC Critical Rev. Surf. Sci. 1(4), 217 (1992).
52. C.-C. Chen and C.M. Lieber, “Synthesis of pure 13C60 and determination of the isotope effect for
fullerene superconductors,” J. Am. Chem. Soc. 114, 3141-3142 (1992).
53. C. Niu and C.M. Lieber, “The local structure of Bi2.2Sr1.8Cu1-xFexOy single crystals determined
by scanning tunneling microscopy,” J. Phys. Chem. 96, 3419-3423 (1992).
54. C. Niu and C.M. Lieber, “Low-temperature growth of the infinite layer phase of SrCuO2 by
pulsed laser deposition,” J. Am. Chem. Soc. 114, 3570-3571 (1992).
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55. Y. Li, J.L. Huang and C.M. Lieber, “Temperature dependence of the energy gap in
Bi2Sr2CaCu2O8 superconductors by high-resolution electron-energy-loss spectroscopy,” Phys.
Rev. Lett. 68, 3240-3243 (1992).
56. Y. Kim and C.M. Lieber, “Machining oxide thin-films with an atomic force microscope: pattern
and object formation on the nanometer scale,” Science 257, 375-377 (1992).
57. Z. Zhang and C.M. Lieber, “Oxygen doping Bi2Sr2CaCu2O8+ superconductors: Variations in the
BiO-layer electronic states determined by scanning tunneling microscopy,” Phys. Rev. B 46,
5845-5848 (1992).
58. H. Dai and C.M. Lieber, “Solid-hexatic-liquid phases in two-dimensional charge-density waves,”
Phys. Rev. Lett. 69, 1576-1579 (1992).
59. J.-L. Huang, Y.-E. Sung and C.M. Lieber, “Field-induced surface modification on the atomic
scale by scanning tunneling microscopy,” Appl. Phys. Lett. 61, 1528-1530 (1992).
60. C. Niu and C.M. Lieber, “Growth of the infinite layer phase of Sr1-xNdxCuO2 by laser ablation,”
Appl. Phys. Lett. 61, 1712-1714 (1992).
61. C. Niu and C.M. Lieber, “Exploiting laser based methods for low-temperature solid-state
synthesis: Growth of a series of metastable (Sr1-xMx)1-CuO2 materials,” J. Am. Chem. Soc. 115,
137-144 (1993).
62. C.C. Chen and C.M. Lieber, “Isotope effect and superconductivity in metal-doped C60,” Science
259, 655 (1993).
63. Z. Zhang and C.M. Lieber, “Measurement of the energy gap in oxygen-annealed
Bi2Sr2CaCu2O8+δ high-Tc superconductors by tunneling spectroscopy,” Phys. Rev. B 47, 3423-
3426 (1993).
64. H. Dai and C.M. Lieber, “Charge density wave pinning and disorder in two dimensions,” J.
Phys. Chem. 97, 2362-2367 (1993).
65. Y. Li and C.M. Lieber, “The energy gap in the high-Tc copper oxide superconductors,” Mod.
Phys. Lett. B. 7, 143 (1993).
66. C.M. Lieber and Y. Kim, “Nanomachining and manipulation with the atomic force microscope,”
Adv. Mat. 5, 392 (1993).
67. Z. Zhang and C.M. Lieber, “Nanotube structure and electronic properties probed by scanning
tunneling microscopy,” Appl. Phys. Lett. 62, 2792-2794 (1993).
68. Y. Li, J. Liu and C.M. Lieber, “Dependence of the energy gap on Tc: Absence of scaling in the
copper oxide superconductors,” Phys. Rev. Lett. 70, 3494-3497 (1993).
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69. D. Zhang, J.R. Norris, P.J. Krusic, E. Wasserman, C.-C. Chen and C.M. Lieber, “Time-resolved
EPR and Fourier transform EPR Study of triplet C60. determinations of T1 and the 13C hyperfine
coupling constant,” J. Phys. Chem. 97, 5886-5889 (1993).
70. C. Niu, Y.Z. Lu and C.M. Lieber, “Experimental realization of the covalent solid carbon nitride,”
Science 261, 334 (1993).
71. H. Dai and C.M. Lieber, “Scanning tunneling microscopy studies of low-dimensional materials:
Charge density wave pinning and melting in two dimensions,” Ann. Rev. Phys. Chem. 44, 237
(1993).
72. C.M. Lieber, “Modification and manipulation of layered materials using scanned probe
microscopies,” The Technology of Proximal Probe Lithography (ed. C.R.K. Marrian, SPIE
Optical Engineering Press, 1993).
73. H. Dai, J. Liu and C.M. Lieber, “Surface pinning and grain boundary formation in magnetic fluxline lattices of Bi2Sr2CaCu2O8+ High-Tc superconductors,” Phys. Rev. Lett. 72, 748-751 (1994).
74. R. Movshovich, J.D. Thompson, C.-C. Chen and C.M. Lieber, “Pressure dependence of the
superconducting transition temperature in nominal Rb0.5Cs2.5C60,” Phys. Rev. B 49, 3619-3621
(1994).
75. J. Liu, Y. Li and C.M. Lieber, “Intrinsic features of Bi2Sr2CaCu2O8+ tunneling spectra: Scaling
and symmetry of the energy gap,” Phys. Rev. B 49, 6234-6238 (1994).
76. C.M. Lieber and Z. Zhang, “Physical properties of metal-doped fullerene superconductors,”
Solid State Physics 48, (eds. H. Ehrenreich and F. Spaepen, Academic Press, 1994).
77. C.M. Lieber and C.C. Chen, “Preparation of fullerenes and fullerene based materials,” Solid
State Physics 48, (eds. H. Ehrenreich and F. Spaepen, Academic Press, 1994).
78. C.M. Lieber, “Scanning tunneling microscopy,” Chem. & Eng. News 72, 28 (1994).
79. C.M. Lieber and Z.J. Zhang, “Synthesis of covalent carbon nitride solids: Alternatives to
diamond?” Adv. Mat. 6, 497 (1994).
80. S. Yoon, H. Dai, J. Liu and C.M. Lieber, “Surface pinning as a determinant of the bulk flux-Line
lattice structure in copper oxide superconductors,” Science 265, 215 (1994).
81. S.M. Argentine, A.H. Francis, C.C. Chen, C.M. Lieber and J.S. Siegel, “Unusual
photoluminescence behavior of C70,” J. Phys. Chem. 98, 7350-7354 (1994).
82. C. Niu and C.M. Lieber, “Thin film synthesis of solids,” Encyclopedia of Inorganic Chemistry 8,
4151-4158 (ed. B. King, John Wiley & Sons, 1994).
83. A.M. Morales, P. Yang and C.M. Lieber, “Preparation of layered Sr2CuO3+ by pulsed laser
deposition: Rational synthesis and doping of a metastable copper oxide material,” J. Am. Chem.
Soc. 116, 8360-8361 (1994).
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84. H. Dai, S. Yoon, J. Liu, R.C. Budhani and C.M. Lieber, “Simultaneous observation of columnar
defects and magnetic flux lines in high-temperature Bi2Sr2CaCu2O8 superconductors,” Science
265, 1552-1555 (1994).
85. C.D. Frisbie, L.F. Rozsnyai, A. Noy, M.S. Wrighton and C.M. Lieber, “Functional group
imaging by chemical force microscopy,” Science 265, 2071-2074 (1994).
86. Z. Yao, S. Yoon, H. Dai, S. Fan and C.M. Lieber, “Path of magnetic flux-lines through high-Tc
copper oxide superconductors,” Nature 371, 777-779 (1994).
87. Z. Zhang and C.M. Lieber, “Characterization of complex materials by scanning tunneling
microscopy: A look at superconductors with high critical temperatures,” Materials Chemistry:
An Emerging Discipline, Advances in Chemistry Series 245 (eds. L. Interrante et al., American
Chemical Society, 1995).
88. U.C. Täuber, H. Dai, D.R. Nelson and C.M. Lieber, “Coulomb gap and correlated vortex pinning
in superconductors,” Phys. Rev. Lett. 74, 5132-5135 (1995).
89. Z.J. Zhang, S. Fan and C.M. Lieber, “Growth and composition of covalent carbon nitride solids,”
Appl. Phys. Lett. 66, 3582-3584 (1995).
90. H. Dai, E.W. Wong, Y.Z. Lu, S. Fan and C.M. Lieber, “Synthesis and characterization of carbide
nanorods,” Nature 375, 769-772 (1995).
91. A. Noy, C.D. Frisbie, L.F. Rozsnyai, M.S. Wrighton and C.M. Lieber, “Chemical force
microscopy: Exploiting chemically-modified tips to quantify adhesion, friction, and functional
group distributions in molecular assemblies,” J. Am. Chem. Soc. 117, 7943-7951 (1995).
92. C.M. Lieber, “Carbon nitride,” Yearbook of Science and Technology 40-42 (ed. S. Parker,
McGraw-Hill, 1995).
93. S. Yoon, Z. Yao, H. Dai and C.M. Lieber, “Elastic properties of flux-line arrays in high-Tc
superconductors probed by two-sided decoration,” Science 270, 270-73 (1995).
94. Z.J. Zhang, P. Yang and C.M. Lieber, “Growth and properties of carbon nitride thin films,” Mat.
Res. Soc. Symp. Proc. 388, 271-80 (1995).
95. C.M. Lieber and Z.J. Zhang, “Carbon nitride solids: Potential alternatives to diamond?” Chem.
Ind. 22, 922-25 (1995).
96. Z.J. Zhang, S. Fan, J.L. Huang and C.M. Lieber, “Pulsed laser deposition and physical properties
of carbon nitride thin films,” J. Elec. Mater. 25, 57-61 (1995).
97. C.M. Lieber, J. Liu and P.E. Sheehan, “Anorganische materialien mit hilfe von
rastersondenmikroskopen verstehen und manipulieren,” Angew. Chem. Int. Ed. Ger. 108, 748-
768 (1996).
98. C.M. Lieber, J. Liu and P.E. Sheehan, “Understanding and manipulating inorganic materials
using scanning probe microscopes,” Angew. Chem. Int. Ed. Engl. 35, 686-704 (1996).
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99. H. Dai, E.W. Wong and C.M. Lieber, “Probing electrical transport in nanomaterials:
Conductivity of individual carbon nanotubes,” Science 272, 523-526 (1996).
100. Z.J. Zhang, S. Fan, J. Huang and C.M. Lieber, “Diamond-like properties in a single phase carbon
nitride solid,” Appl. Phys. Lett. 68, 2639-2641 (1996).
101. J. Liu, J.L. Huang and C.M. Lieber, “Probing complex low-dimensional solids with scanning
probe microscopes: From charge density waves to high-temperature superconductivity,” J. Vac.
Sci. Tech. 14, 1064-1069 (1996).
102. Z.J. Zhang, J.L. Huang, S. Fan and C.M. Lieber, “Phases and physical properties of carbon
nitride thin films prepared by pulsed laser deposition,” Mat. Sci. & Eng. A 209, 5-9 (1996).
103. P.E. Sheehan and C.M. Lieber, “Nanotribology and nanofabrication of MoO3 structures by force
microscopy,” Science 272, 1158-61 (1996).
104. J. Liu and C.M. Lieber, “Electron tunneling microscopy: A direct probe of metal substitution in
BiSrCaCuO superconductors,” Inorg. Chim. Acta 243, 305-308 (1996).
105. C.M. Lieber, E.W. Wong, H. Dai, B.W. Maynor and L.D. Burns, “Growth and structure of
carbide nanorods,” Mat. Res. Soc. Symp. Proc. 410, 103-112 (1996).
106. E.W. Wong, B.W. Maynor, L.D. Burns and C.M. Lieber, “Growth of metal carbide nanotubes
and nanorods,” Chem. Mater. 8, 2041-2046 (1996).
107. P. Yang and C.M. Lieber, “Nanorod-superconductor composites: A pathway to high critical
current density materials,” Science 273, 1836-1840 (1996).
108. C.M. Lieber, “Chemical force microscopy,” Yearbook of Science and Technology 85-88 (ed. S.
Parker, McGraw-Hill, 1996).
109. P.E. Sheehan and C.M. Lieber, “Nanomachining, manipulation and fabrication by force
microscopy,” Nanotechnol. 7, 236-240 (1996).
110. J. Zhang, J. Liu, J.L. Huang, P. Kim and C.M. Lieber, “Creation of nanocrystals through a solidsolid phase transition induced by an STM tip,” Science 274, 757-760 (1996).
111. A.J. Stevens, T. Koga, C.B. Agee, M.J. Aziz and C.M. Lieber, “Stability of carbon nitride
materials at high pressure and temperature,” J. Am. Chem. Soc. 118, 10900-10901 (1996).
112. P. Kim, Z. Yao and C.M. Lieber, “Structure of vortex arrays by magnetic decoration,” 8th IWCC
Conf. Proc. 3-10 (World Scientific, 1996).
113. P. Kim, Z. Yao and C.M. Lieber, “Vortex lattice structure in Bi2Sr2CaCu2O8+ at high
temperatures,” Phys. Rev. Lett. 77, 5118-5121 (1996).
11
114. D.V. Vezenov, A. Noy, L.F. Rozsnyai and C.M. Lieber, “Force titrations and ionization state
sensitive imaging of functional groups in aqueous solutions by chemical force microscopy,” J.
Am. Chem. Soc. 119, 2006-2015 (1997).
115. M.R. Eskildsen, P.L. Gammel, B.P. Barber, U. Yaron, A.P. Ramirez, D.A. Huse, D.J. Bishop, C.
Bolle, C.M. Lieber, S. Oxx, S. Sridhar, N.H. Andersen, K. Mortensen and P.C. Canfield,
“Observation of a field-driven structural phase transition in the flux line lattice in ErNi2B2C,”
Phys. Rev. Lett. 78, 1968-1971 (1997).
116. J.D. Harper, S.S. Wong, C.M. Lieber and P.T. Lansbury Jr., “Observation of metastable A
amyloid protofibrils by atomic force microscopy,” Chem. Biol. 4, 119-125 (1997).
117. P. Yang, Z.J. Zhang, J. Hu and C.M. Lieber, “Pulsed laser deposition of diamond-like carbon
thin films: Ablation dynamics and growth,” Mater. Res. Soc. Symp. Proc. 438, 593-598 (1997).
118. C.M. Lieber, A.M. Morales, P.E. Sheehan, E.W. Wong and P. Yang, “One-dimensional
nanostructures: Rational synthesis, novel properties and applications,” Proceedings of the Robert
A. Welch Foundation 40th Conference on Chemical Research: Chemistry on the Nanometer
Scale 165-187 (Robert A. Welch Foundation, 1997).
119. P. Yang and C.M. Lieber, “Columnar defect formation in nanorod/Tl2Ba2Ca2Cu3Oz
superconducting composites,” Appl. Phys. Lett. 70, 3158-3160 (1997).
120. M.R. Eskildsen, P.L. Gammel, B.P. Barber, A.P. Ramirez, D.J. Bishop, N.H. Andersen, K.
Mortensen, C.A. Bolle, C.M. Lieber and P.C. Canfield, “Structural stability of the square flux
line lattice in YNI2B2C and LuNi2B2C studied with small angle neutron scattering,” Phys. Rev.
Lett. 79, 487-490 (1997).
121. A. Noy, D.V. Vezenov and C.M. Lieber, “Chemical force microscopy,” Annu. Rev. Mater. Sci.
27, 381-421 (1997).
122. A. Noy, D. Vezenov, J.F. Kayyem, T.J. Meade and C.M. Lieber, “Stretching and breaking
duplex DNA by chemical force microscopy,” Chem. Biol. 4, 519-527 (1997).
123. C.M. Lieber, D. Vezenov, A. Noy and C. Sanders, “Chemical force microscopy,” Microscopy
and Microanalysis 3, 1253-1254 (1997).
124. C.M. Lieber and P. Yang, “High-temperature superconductors,” Science 277, 1909-1910 (1997).
125. E.W. Wong, P.E. Sheehan and C.M. Lieber, “Nanobeam mechanics: Elasticity, strength and
toughness of nanorods and nanotubes,” Science 277, 1971-1975 (1997).
126. J. Zhang, J. Liu, J.L. Huang, P. Kim and C.M. Lieber, “Creation of nanocrystals via a tipinduced solid-solid transformation,” Mater. Res. Soc. Symp. Proc. 466, 89-94 (1997).
127. P. Yang and C.M. Lieber, “Nanostructured high-temperature superconductors: Creation of
strong-pinning columnar defects in nanorod/superconductor composites,” J. Mater. Res. 12,
2981-2996 (1997).
12
128. J.D. Harper, C.M. Lieber and P. T. Lansbury, “Atomic force microscopic imaging of seeded
fibril formation and fibril branching by the Alzheimer's disease amyloid- protein,” Chem. Biol.
4, 951-959 (1997).
129. T. W. Odom, J.L. Huang, P. Kim and C.M. Lieber, “Atomic structure and electronic properties
of single-walled carbon nanotubes,” Nature 391, 62-64 (1998).
130. A.M. Morales and C.M. Lieber, “A laser ablation method for the synthesis of crystalline
semiconductor nanowires,” Science 279, 208-211 (1998).
131. S.S. Wong, J.D. Harper, P.T. Lansbury and C.M. Lieber, “Carbon nanotube tips: High-resolution
probes for imaging biological systems,” J. Am. Chem. Soc. 120, 603-604 (1998).
132. J. Hu, P. Yang and C.M. Lieber, “Nitrogen-driven sp3 to sp2 transformation in carbon nitride
materials,” Phys. Rev. B 57, R3185-R3188 (1998).
133. A. Noy, C.H. Sanders, D.V. Vezenov, S.S. Wong and C.M. Lieber, “Chemically-sensitive
imaging in tapping mode by chemical force microscopy: Relationship between phase lag and
adhesion,” Langmuir 14, 1508-1511 (1998).
134. D.V. Vezenov, A. Noy and C.M. Lieber, “Chemical force microscopy: Probing and imaging
interactions between functional groups,” Proceedings of the Scanning Probe Microscopy in
Polymers Symposium 312-320 (American Chemical Society, 1998).
135. J. Hu, P. Yang and C.M. Lieber, “Nitrogen-driven structural transformation in carbon nitride
materials,” Appl. Surf. Sci. 127-129, 569-573 (1998).
136. S.S. Wong, E. Joselevich, A.T. Woolley, C.L. Cheung and C.M. Lieber, “Covalently
functionalized nanotubes as nanometer probes for chemistry and biology,” Nature 394, 52-55
(1998).
137. C.M. Lieber, “One-dimensional nanostructures: Chemistry, physics and applications,” Solid
State Comm. 107, 607-616 (1998).
138. S.S. Wong, A.T. Woolley, E. Joselevich, C.L. Cheung and C.M. Lieber, “Covalentlyfunctionalized single-walled carbon nanotube probe tips for chemical force microscopy,” J. Am.
Chem. Soc. 120, 8557-8558 (1998).
139. T.W. Odom, J.L. Huang, P. Kim, M. Ouyang and C.M. Lieber, “Scanning tunneling microscopy
and spectroscopy studies of single wall carbon nanotubes,” J. Mater. Res. 13, 2380-2388 (1998).
140. S.S. Wong, A.T. Woolley, T.W. Odom, J.L. Huang, P. Kim, D.V. Vezenov and C.M. Lieber,
“Single-walled carbon nanotube probes for high-resolution nanostructure imaging,” Appl. Phys.
Lett. 73, 3465-3467 (1998).
141. P. Kim, T.W. Odom, J.-L. Huang and C.M. Lieber, “Electronic density of states of atomically
resolved single-walled carbon nanotubes: Van Hove singularities and end states,” Phys. Rev.
Lett. 82, 1225-1228 (1999).
13
142. J.H. Hafner, C.L. Cheung and C.M. Lieber, “Growth of nanotubes for probe microscopy tips,”
Nature 398, 761-762 (1999).
143. J. Hu, M. Ouyang, P. Yang and C.M. Lieber, “Controlled growth and electrical properties of
heterojunctions of carbon nanotubes and silicon nanowires,” Nature 399, 48-51 (1999).
144. J. Hu, T.W. Odom and C.M. Lieber, “Chemistry and physics in one dimension: Synthesis and
properties of nanowires and nanotubes,” Acc. Chem. Res. 32, 435-445 (1999).
145. S.S. Wong, A.T. Woolley, E. Joselevich and C.M. Lieber, “Functionalization of carbon nanotube
AFM probes using tip-activated gases,” Chem. Phys. Lett. 306, 219 (1999).
146. H. Dai, J. Liu and C.M. Lieber, “Elucidating complex charge density wave structures in lowdimensional materials by scanning tunneling microscopy,” Advances in the Crystallographic and
Microstructural Analysis of Charge Density Wave Modulated Crystals (eds. F.W. Boswell and
J.C. Bennett, Kluwer Academic, 1998).
147. J.D. Harper, S.S. Wong, C.M. Lieber and P.T. Lansbury, Jr., “Assembly of A amyloid
protofibrils: An in vitro model for a possible early event in Alzheimer’s disease,” Biochem. 38,
8972-8980 (1999).
148. A. Yazdani and C.M. Lieber, “Up close and personal to atoms,” Nature 401, 227-230 (1999).
149. J.H. Hafner, C.L. Cheung and C.M. Lieber, “Direct growth of single-walled carbon nanotube
scanning probe microscopy tips,” J. Am. Chem. Soc. 121, 9750-9751 (1999).
150. J. Wang, K.C. Rose and C.M. Lieber, “Load-independent friction: MoO3 nanocrystal lubricants,”
J. Phys. Chem. B 103, 8405-8409 (1999).
151. P. Kim, Z. Yao, C.A. Bolle and C.M. Lieber, “Structure of flux line lattices with weak disorder
at large length scales,” Phys. Rev. B 60, R12589-R12592 (1999).
152. P. Kim, T.W. Odom, J.L. Huang and C.M. Lieber, “Electronic structures and applications of
carbon nanotubes,” Electronic Properties of Novel Materials Science and Technology of
Molecular Nanostructures: Xiii International Winterschool (AIP Conference Proceedings) (eds.
H. Kuzmany et al., Springer Verlag, 1999).
153. P. Kim and C.M. Lieber, “Nanotube nanotweezers,” Science 286, 2148 - 2150 (1999).
154. L. Venkataraman and C.M. Lieber, “Molybdenum selenide molecular wires as one-dimensional
conductors,” Phys. Rev. Lett. 83, 5334-5337 (1999).
155. X. Duan and C.M. Lieber, “Laser-assisted catalytic growth of single crystal GaN nanowires,” J.
Am. Chem. Soc. 122, 188-189 (2000).
156. X. Duan and C.M. Lieber, “General synthesis of compound semiconductor nanowires” Adv.
Mater. 12, 298-302 (2000).
14
157. X. Duan, J. Wang and C.M. Lieber, “Synthesis and optical properties of gallium arsenide
nanowires,” Appl. Phys. Lett. 76, 1116-1118 (2000).
158. T.W. Odom, J.-L. Huang, P. Kim and C.M. Lieber, “Structure and electronic properties of
carbon nanotubes,” J. Phys. Chem. B 104, 2794-2809 (2000).
159. C.L. Cheung, J.H. Hafner and C.M. Lieber, “Carbon nanotube atomic force microscopy tips:
Direct growth by chemical vapor deposition and application to high-resolution imaging,” Proc.
Natl. Acad. Sci. USA 97, 3809-3813 (2000).
160. C.L. Cheung, J.H. Hafner, T.W. Odom, K. Kim and C.M. Lieber, “Growth and fabrication with
single-walled carbon nanotube probe microscopy tips,” Appl. Phys. Lett. 76, 3136-3138 (2000).
161. Q. Wei and C.M. Lieber, “Solution-based synthesis of magnesium oxide nanorods,” Mat. Res.
Soc. Symp. Proc. 581, 3-7 (2000).
162. Q. Wei and C.M. Lieber, “Synthesis of single crystal bismuth-telluride and lead-telluride
nanowires for new thermoelectrical materials,” Mat. Res. Soc. Symp. Proc. 581, 219-223 (2000).
163. Y. Cui, X. Duan, J. Hu and C.M. Lieber, “Doping and electrical transport in silicon nanowires,”
J. Phys. Chem. B 104, 5213-5216 (2000).
164. A.T. Woolley, C. Guillemette, C.L. Cheung, D.E. Housman and C.M. Lieber, “Direct
haplotyping of kilobase-size DNA using carbon nanotube probes,” Nat. Biotechnol. 18, 760-763
(2000).
165. T. Rueckes, K. Kim, E. Joselevich, G.Y. Tseng, C.L. Cheung and C.M. Lieber, “Carbon
nanotube-based nonvolatile random access memory for molecular computing,” Science 289, 94-
97 (2000).
166. M.S. Gudiksen and C.M. Lieber, “Diameter-selective synthesis of semiconductor nanowires,” J.
Am. Chem. Soc. 122, 8801-8802 (2000).
167. P.D. Ashby, L. Chen and C.M. Lieber, “Probing intermolecular forces and potentials with
magnetic feedback chemical force microscopy,” J. Am. Chem. Soc. 122, 9467-9472 (2000).
168. A.T. Woolley, C.L. Cheung, J.H. Hafner and C.M. Lieber, “Structural biology with carbon
nanotube AFM probes,” Chem. Biol. 7, R193-R204 (2000).
169. T.W. Odom, J.L. Huang, C.L. Cheung and C.M. Lieber, “Magnetic clusters on single-walled
carbon nanotubes: The Kondo effect in a one-dimensional host,” Science 290, 1549-1552 (2000).
170. P. Kim, J. Zhang and C.M. Lieber, “Charge density wave formation in nanocrystals,” Solid State
Physics (eds. H. Ehrenreich and F. Spaepen, Academic Press, 2000).
171. X. Duan, Y. Huang, Y. Cui, J. Wang and C.M. Lieber, “Indium phosphide nanowires as building
blocks for nanoscale electronic and optoelectronic devices,” Nature 409, 66-69 (2001).
15
172. M. Ouyang, J.L. Huang, C.L. Cheung and C.M. Lieber, “Atomically resolved single-walled
carbon nanotube intramolecular junctions,” Science 291, 97-100 (2001).
173. M. Bockrath, W. Liang, D. Bozovic, J.H. Hafner, C.M. Lieber, M. Tinkham and H. Park,
“Resonant electron scattering by defects in single-walled carbon nanotubes,” Science 291, 283-
285 (2001).
174. Y. Huang, X. Duan, Q. Wei and C.M. Lieber, “Directed assembly of one-dimensional
nanostructures into functional networks,” Science 291, 630-633 (2001).
175. J.H. Hafner, C.-L. Cheung, T.H. Oosterkamp and C.M. Lieber, “High-yield assembly of
individual single-walled carbon nanotube tips for scanning probe microscopies,” J. Phys. Chem.
B 105, 743-746 (2001).
176. A. Jorio, R. Saito, J.H. Hafner, C.M. Lieber, M. Hunter, T. McClure, G. Dresselhaus and M.S.
Dresselhaus, “Structural (n,m) determination of isolated single-wall carbon nanotubes by
resonant Raman scattering,” Phys. Rev. Lett. 86, 1118-1121 (2001).
177. Y. Cui and C.M. Lieber, “Functional nanoscale electronic devices assembled using silicon
nanowire building blocks,” Science 291, 851-853 (2001).
178. T.W. Odom, J.H. Hafner and C.M. Lieber, “Scanning probe microscopy studies of carbon
nanotubes,” Topics Appl. Phys. 80, 173-211 (eds. M.S. Dresselhaus et al., Springer-Verlag,
2001).
179. Y. Cui, L.J. Lauhon, M.S. Gudiksen, J. Wang and C.M. Lieber, “Diameter-controlled synthesis
of single-crystal silicon nanowires,” Appl. Phys. Lett. 78, 2214-2216 (2001).
180. M. Ouyang, J.L. Huang, C.L. Cheung and C.M. Lieber, “Energy gaps in “metallic” single-walled
carbon nanotubes,” Science 292, 702-705 (2001).
181. M.S. Gudiksen, J. Wang and C.M. Lieber, “Synthetic control of the diameter and length of single
crystal semiconductor nanowires,” J. Phys. Chem. B 105, 4062-4064 (2001).
182. D. Bozovic, M. Bockrath, J.H. Hafner, C.M. Lieber, H. Park and M. Tinkham, “Electronic
properties of mechanically induced kinks in single-walled carbon nanotubes,” Appl. Phys. Lett.
78, 3693-3695 (2001).
183. J.H. Hafner, C.L. Cheung, A.T. Woolley and C.M. Lieber, “Structural and functional imaging
with carbon nanotube AFM probes,” Prog. Biophys. Mol. Biol. 77, 73-110 (2001).
184. Y. Cui, Q. Wei, H. Park and C.M. Lieber, “Nanowire nanosensors for highly sensitive and
selective detection of biological and chemical species,” Science 293, 1289-1292 (2001).
185. J. Wang, M.S. Gudiksen, X. Duan, Y. Cui and C.M. Lieber, “Highly polarized
photoluminescence and photodetection from single indium phosphide nanowires,” Science 293,
1455-1457 (2001).
186. C.M. Lieber, “The incredible shrinking circuit,” Sci. Am. 285, 50-56 (2001).
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187. Y. Huang, X. Duan, Y. Cui, L. Lauhon, K. Kim and C.M. Lieber, “Logic gates and computation
from assembled nanowire building blocks,” Science 294, 1313-1317 (2001).
188. G.R. Schnitzler, C.L. Cheung, J.H. Hafner, A.J. Saurin, R.E. Kingston and C.M. Lieber, “Direct
imaging of human SWI/SNF remodeled mono- and polynucleosomes by atomic force
microscopy employing carbon nanotube tips,” Mol. Cell. Biol. 21, 8504-8511 (2001).
189. A. Jorio, A.G. Souza Filho, G. Dresselhaus, M.S. Dresselhaus, R. Saito, J.H. Hafner, C.M.
Lieber, F.M. Matinaga, M.S.S. Dantas and M.A. Pimenta, “Joint density of electronic states for
one isolated single-wall carbon nanotube studied by resonant Raman scattering,” Phys. Rev. B
63, 245416-1 – 245416-4 (2001).
190. A.G. Souza Filho, A. Jorio, J.H. Hafner, C.M. Lieber, R. Saito, M.A. Pimenta, G. Dresselhaus
and M.S. Dresselhaus, “Electronic transition energy Eii for an isolated (n,m) single-wall carbon
nanotube obtained by anti-Stokes/Stokes resonant Raman intensity ratio,” Phys. Rev. B 63,
241404-1 – 241404-4 (2001).
191. M.A. Pimenta, A. Jorio, S.D.M. Brown, A.G. Souza Filho, G. Dresselhaus, J.H. Hafner, C.M.
Lieber, R. Saito and M.S. Dresselhaus, “Diameter dependence of the Raman D-band in isolated
single-wall carbon nanotubes,” Phys. Rev. B 64, 041401-1 – 041401-4 (2001).
192. R. Saito, A. Jorio, J.H. Hafner, C.M. Lieber, M. Hunter, T. McClure, G. Dresselhaus and M.S.
Dresselhaus, “Chirality-dependent G-band Raman intensity of carbon nanotubes,” Phys. Rev. B
64, 085312-1 – 085312-7 (2001).
193. E.T. Powers, S.I. Yang, C.M. Lieber and J.W. Kelly “Ordered Langmuir-Blodgett films of
amphiphilic -hairpin peptides imaged by atomic force microscopy,” Angew. Chem. Int. Ed. 41,
127-130 (2002).
194. M.S. Gudiksen, L.J. Lauhon, J. Wang, D. Smith and C.M. Lieber, “Growth of nanowire
superlattice structures for nanoscale photonics and electronics,” Nature 415, 617-620 (2002).
195. M. Ouyang, J.-L. Huang and C.M. Lieber, “One-dimensional energy dispersion of single-walled
carbon nanotubes by resonant electron scattering,” Phys. Rev. Lett. 88, 066804-1 – 066804-4
(2002).
196. C.M. Lieber, “Nanowire superlattices,” Nano Lett. 2, 81-82 (2002).
197. Y. Huang, X. Duan, Y. Cui and C.M. Lieber, “Gallium nitride nanowire nanodevices,” Nano
Lett. 2, 101-104 (2002).
198. T.W. Odom, J.L. Huang and C.M. Lieber, “STM studies of single-walled carbon nanotubes,” J.
Phys.: Condensed Matter 14, R145-R167 (2002).
199. C.L. Cheung, A. Kurtz, H. Park and C.M. Lieber, “Diameter-controlled synthesis of carbon
nanotubes,” J. Phys. Chem. B 106, 2429-2433 (2002).
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200. L. Chen, K.A. Haushalter, C.M. Lieber and G.L. Verdine, “Direct visualization of a DNA
glycosylase searching for damage,” Chem. Biol. 9, 345-350 (2002).
201. M.S. Gudiksen, J. Wang and C.M. Lieber, “Size-dependent photoluminescence from single
indium phosphide nanowires,” J. Phys. Chem. B 106, 4036-4039 (2002).
202. X. Duan, Y. Huang, Y. Cui and C.M. Lieber, “Nonvolatile memory and programmable logic
from molecule-gated nanowires,” Nano Lett. 2, 487-490 (2002).
203. M. Ouyang, J.L. Huang and C.M. Lieber, “Scanning tunneling microscopy studies of the onedimensional electronic properties of single-walled carbon nanotubes,” Annu. Rev. Phys. Chem.
53, 201-220 (2002).
204. T.W. Odom, J. Huang and C.M. Lieber, “Single-walled carbon nanotubes. From fundamental
studies to new device concepts,” Ann. N. Y. Acad. Sci. 960, 203-215 (2002).
205. D.V. Vezenov, A.V. Zhuk, G.M. Whitesides and C.M. Lieber, “Chemical force spectroscopy in
heterogeneous systems: Intermolecular interactions involving epoxy polymer, mixed
monolayers, and polar solvents,” J. Am. Chem. Soc. 124, 10578-10588 (2002).
206. C.M. Lieber, “Nanoscience and nanotechnology: Building a big future from small things,”
Update 6-9 (New York Academy of Sciences, October 2002).
207. L.J. Lauhon, M.S. Gudiksen, D. Wang and C.M. Lieber, “Epitaxial core-shell and core-multishell nanowire heterostructures,” Nature 420, 57-61 (2002).
208. E. Joselevich and C.M Lieber, “Vectorial growth of metallic and semiconducting single-wall
carbon nanotubes” Nano Lett. 2, 1137-1141 (2002).
209. M. Ouyang, J.L. Huang and C.M. Lieber, “Fundamental electronic properties and applications of
single-walled carbon nanotubes” Acc. Chem. Res. 35, 1018-1025 (2002).
210. A.G. Souza Filho, A. Jorio, G. Dresselhaus, M.S. Dresselhaus, R. Saito, A.K. Swan, M.S. Unlu,
B.B. Goldberg, J.H. Hafner, C.M. Lieber and M.A. Pimenta “Effect of quantized electronic
states on the dispersive Raman features in individual single-wall carbon nanotubes,” Phys. Rev
B: Condens. Matter Mater. Phys. 65, 035404/1-035404/6 (2002).
211. A.G. Souza Filho, A. Jorio, A.K. Swan, M.S. Unlu, B.B. Goldberg, R. Saito, J.H. Hafner, C.M.
Lieber, M.A. Pimenta, G. Dresselhaus and M.S. Dresselhaus “Anomalous two-peak G’-band
Raman effect in one isolated single-wall carbon nanotube,” Phys. Rev B: Condens. Matter
Mater. Phys. 65, 085417/1-035404/8 (2002).
212. A.G. Souza Filho, A. Jorio, G.G. Samsonidze, G. Dresselhaus, M.S. Dresselhaus, A.K. Swan,
M.S. Unlu, B.B. Goldberg, R. Saito, J.H. Hafner, C.M. Lieber and M.A. Pimenta “Probing the
electronic trigonal warping effect in individual single-wall carbon nanotubes using phonon
spectra,” Chem. Phys Lett. 354, 62-68 (2002).
213. A. Jorio, A.G. Souza Filho, V.W Brar, A.K. Swan, M.S. Unlu, B.B. Goldberg, A. Righi, J.H.
Hafner, C.M. Lieber, R. Saito, G. Dresselhaus and M.S. Dresselhaus “Polarized resonant Raman
18
study of isolated single-wall carbon nanotubes: Symmetry selection rules, dipolar and multipolar
antenna effects,” Phys. Rev B: Condens. Matter Mater. Phys. 65, 121402/1-035404/4 (2002).
214. A. Jorio, A.G. Souza Filho, G. Dresselhaus, M.S. Dresselhaus, A.K. Swan, M.S. Unlu, B.B.
Goldberg, M.A. Pimenta, J.H. Hafner, C.M. Lieber and R. Saito “G-band resonant Raman study
of 62 isolated single-wall carbon nanotubes,” Phys. Rev B: Condens. Matter Mater. Phys. 65,
155412/1-155412/9 (2002).
215. A.G. Souza Filho, A. Jorio, G. Dresselhaus, M.S. Dresselhaus, A.K. Swan, M.S. Unlu, B.B.
Goldberg, J.H. Hafner, C.M. Lieber, M.A. Pimenta and R. Saito “Dependence of the secondorder G’-band profile on the electronic structure of single-wall nanotubes,” Mater. Res. Soc.
Symp. Proc. 706, 181-186 (2002).
216. A. Jorio, A.G. Souza Filho, G. Dresselhaus, M.S. Dresselhaus, A.K. Swan, M.S. Unlu, B.B.
Goldberg, M.A. Pimenta, J.H. Hafner, C.M. Lieber and R. Saito, “G-band Raman spectra of
isolated single wall carbon nanotubes: Diameter and chirality dependence,” Mater. Res. Soc.
Symp. Proc. 706, 187-192 (2002).
217. A. Jorio, F.M. Matinaga, A. Righi, M.S.S. Dantas, M.A. Pimenta, A.G. Souza Filho, J. Mendes
Filho, J.H. Hafner, C.M. Lieber, R. Saito, G. Dresselhaus and M.S. Dresselhaus, “Resonance
Raman scattering: Nondestructive and noninvasive technique for structural and electronic
characterization of isolated single-wall carbon nanotubes,” Brazilian J. Phys. 32, 921-924
(2002).
218. X. Duan, Y. Huang, R. Agarwal and C.M. Lieber, “Single-nanowire electrically driven lasers,”
Nature 421, 241-245 (2003).
219. Y. Cui, Z. Zhong, D. Wang, W.U. Wang and C.M. Lieber, “High performance silicon nanowire
field effect transistors,” Nano Lett. 3, 149-152 (2003).
220. X. Duan, Y. Huang and C.M. Lieber, “Nanowire nanocircuits,” McGraw-Hill Yearbook of
Science and Technology 272-276 (eds. M.D. Licker et al., McGraw-Hill, 2003).
221. Z. Zhong, F. Qian, D. Wang and C.M. Lieber, “Synthesis of p-type gallium nitride nanowires for
electronic and photonic nanodevices,” Nano Lett. 3, 343-346 (2003).
222. M.C. McAlpine, R.S. Friedman and C.M. Lieber, “Nanoimprint lithography for hybrid plastic
electronics,” Nano Lett. 3, 443-445 (2003).
223. D. Wang and C.M. Lieber, “Inorganic materials: Nanocrystals branch out,” Nat. Mater. 2, 355-
356 (2003).
224. X. Duan, Y. Huang, Y. Cui and C.M. Lieber, “Nanowire nanoelectronics assembled from the
bottom-up” Molecular Nanoelectronics 199-227 (eds. M.A. Reed and T. Lee, American
Scientific, 2003).
225. D. Whang, S. Jin and C.M. Lieber, “Nanolithography using hierarchically assembled nanowire
masks,” Nano Lett. 3, 951-954 (2003).
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226. C.M. Lieber, “Nanoscale science and technology: Building a big future from small things,” MRS
Bull. 28, 486-491 (2003).
227. C.J. Barrelet, Y. Wu, D.C. Bell and C.M. Lieber, “Synthesis of CdS and ZnS nanowires using
single-source molecular precursors,” J. Am. Chem. Soc. 125, 11498-11499 (2003).
228. D. Whang, S. Jin, Y. Wu and C.M. Lieber, “Large-scale hierarchical organization of nanowire
arrays for integrated nanosystems,” Nano Lett. 3, 1255-1259 (2003).
229. Y. Cui, X. Duan, Y. Huang and C.M. Lieber, “Nanowires as building blocks for nanoscale
science and technology,” Nanowires and Nanobelts – Materials, Properties and Devices 3-68
(ed. Z.L. Wang, Kluwer Academic/Plenum, 2003).
230. M.C. McAlpine, R.S. Friedman, S. Jin, K. Lin, W.U. Wang and C.M. Lieber, “High-performance
nanowire electronics and photonics on glass and plastic substrates,” Nano Lett. 3, 1531-1535
(2003).
231. Z. Zhong, D. Wang, Y. Cui, M.W. Bockrath and C.M. Lieber, “Nanowire crossbar arrays as
address decoders for integrated nanosystems,” Science 302, 1377-1379 (2003).
232. D. Bozovic, M. Bockrath, J.H. Hafner, C.M. Lieber, H. Park and M. Tinkham, “Plastic
deformations in mechanically strained single-walled carbon nanotubes,” Phys. Rev. B 67,
033407/1-033407/4 (2003).
233. D.V. Vezenov, A. Noy and C.M. Lieber, “The effect of liquid-induced adhesion changes on the
interfacial shear strength between self-assembled monolayers,” J. Adhesion Sci. Technol. 17,
1385-1401 (2003).
234. M.M. Ziegler, C.A. Picconatto, J.C. Ellenbogen, A. DeHon, D. Wang, Z. Zhong and C.M.
Lieber, “Scalability simulations for nanomemory systems integrated on the molecular scale,”
Ann. N.Y. Acad. Sci. 1006, 312-330 (2003).
235. J. Hahm and C.M. Lieber, “Direct ultrasensitive electrical detection of DNA and DNA sequence
variations using nanowire nanosensors,” Nano Lett. 4, 51-54 (2004).
236. Y. Wu, Y. Cui, L. Huynh, C.J. Barrelet, D.C. Bell and C.M. Lieber, “Controlled growth and
structures of molecular-scale silicon nanowires,” Nano Lett. 4, 433-436 (2004).
237. D. Wang, F. Qian, C. Yang, Z. Zhong and C.M. Lieber, “Rational growth of branched and
hyperbranched nanowire structures,” Nano Lett. 4, 871-874 (2004).
238. S. Jin, D. Whang, M.C. McAlpine, R.S. Friedman, Y. Wu and C.M. Lieber, “Scalable
interconnection and integration of nanowire devices without registration,” Nano Lett. 4, 915-919
(2004).
239. A.B. Greytak, L.J. Lauhon, M.S. Gudiksen and C.M. Lieber, “Growth and transport properties of
complementary germanium nanowire field-effect transistors,” Appl. Phys. Lett. 84, 4176-4178
(2004).
20
240. L.J. Lauhon, M.S. Gudiksen and C.M. Lieber, “Semiconductor nanowire heterostructures,” Phil.
Trans. R. Soc. Lond. A 362, 1247-1260 (2004).
241. Y. Wu, J. Xiang, C. Yang, W. Lu and C.M. Lieber, “Single-crystal metallic nanowires and
metal/semiconductor nanowire heterostructures,” Nature 430, 61-65 (2004).
242. D. Whang, S. Jin and C.M. Lieber, “Large-scale hierarchical organization of nanowires for
functional nanosystems,” Japanese J. Appl. Phys. 43, 4465-4470 (2004).
243. D.C. Bell, Y. Wu, C.J. Barrelet, S. Gradečak, J. Xiang, B.P. Timko and C.M. Lieber, “Imaging
and analysis of nanowires,” Microscop. Res. Tech. 64, 373-389 (2004).
244. L. Chen, C.L. Cheung, P.D. Ashby and C.M. Lieber, “Single-walled carbon nanotube AFM
probes: Optimal imaging resolution of nanoclusters and biomolecules in ambient and fluid
environments,” Nano Lett. 4, 1725-1731 (2004).
245. F. Patolsky, G. Zheng, O. Hayden, M. Lakadamyali, X. Zhuang and C.M. Lieber, “Electrical
detection of single viruses,” Proc. Natl. Acad. Sci. USA 101, 14017-14022 (2004).
246. F. Qian, Y. Li, S. Gradečak, D. Wang, C.J. Barrelet and C.M. Lieber, “Gallium nitride-based
nanowire radial heterostructures for nanophotonics,” Nano Lett. 4, 1975-1979 (2004).
247. C.J. Barrelet, A.B. Greytak and C.M. Lieber, “Nanowire photonic circuit elements,” Nano Lett.
4, 1981-1985 (2004).
248. G. Zheng, W. Lu, S. Jin and C.M. Lieber, “Synthesis and fabrication of high-performance n-type
silicon nanowire transistors,” Adv. Mater. 16, 1890-1893 (2004).
249. Y. Huang and C.M. Lieber, “Integrated nanoscale electronics and optoelectronics: Exploring
nanoscale science and technology through semiconductor nanowires,” Pure Appl. Chem. 76,
2051-2068 (2004).
250. P.D. Ashby and C.M. Lieber, “Brownian force profile reconstruction of interfacial 1-nonanol
solvent structure,” J. Am. Chem. Soc. 126, 16973-16980 (2004).
251. Y. Huang, X. Duan and C.M. Lieber, “Nanowires for integrated multicolor nanophotonics,”
Small 1, 142-147 (2005).
252. W.U. Wang, C. Chen, K. Lin, Y. Fang and C.M. Lieber, “Label-free detection of smallmolecule-protein interactions by using nanowire nanosensors,” Proc. Natl. Acad. Sci. USA 102,
3208-3212 (2005).
253. F. Patolsky and C.M. Lieber, “Nanowire nanosensors,” Materials Today 8, 20-28 (2005).
254. Y. Huang, X. Duan and C.M. Lieber, “Semiconductor nanowires: Nanoscale electronics and
optoelectronics,” Dekker Encyclopedia of Nanoscience and Nanotechnology (ed. J.A. Schwarz,
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21
255. X. Duan and C.M. Lieber, “Semiconductor nanowires: rational synthesis,” Dekker Encyclopedia
of Nanoscience and Nanotechnology (ed. J.A. Schwarz, Marcel Dekker, Inc., 2005).
256. R.S. Friedman, M.C. McAlpine, D.S. Ricketts, D. Ham and C.M. Lieber, “High-speed integrated
nanowire circuits,” Nature 434, 1085 (2005).
257. R. Agarwal, C.J. Barrelet and C.M. Lieber, “Lasing in single cadmium sulfide nanowire optical
cavities,” Nano Lett. 5, 917-920 (2005).
258. P.D. Ashby and C.M. Lieber, “Ultra-sensitive imaging and interfacial analysis of patterned
hydrophilic SAM surfaces using energy dissipation chemical force microscopy,” J. Am. Chem.
Soc. 127, 6814-6818 (2005).
259. Z. Zhong, Y. Fang, W. Lu and C.M. Lieber, “Coherent single charge transport in molecular-scale
silicon nanowires,” Nano Lett. 5, 1143-1146 (2005).
260. M.C. McAlpine, R.S. Friedman and C.M. Lieber, “High-performance nanowire electronics and
photonics and nanoscale patterning on flexible plastic substrates,” Proc. IEEE 93, 1357-1363
(2005).
261. W. Lu, J. Xiang, B.P. Timko, Y. Wu and C.M. Lieber, “One-dimensional hole gas in
germanium/silicon nanowire heterostructures,” Proc. Natl. Acad. Sci. USA 102, 10046-10051
(2005).
262. P.V. Radovanovic, C.J. Barrelet, S. Gradečak, F. Qian and C.M. Lieber, “General synthesis of
manganese-doped II-VI and III-V semiconductor nanowires,” Nano Lett. 5, 1407-1411 (2005).
263. G. Zheng, F. Patolsky, Y. Cui, W.U. Wang and C.M. Lieber, “Multiplexed electrical detection of
cancer markers with nanowire sensor arrays,” Nat. Biotechnol. 23, 1294-1301 (2005).
264. A.B. Greytak, C.J. Barrelet, Y. Li and C.M. Lieber, “Semiconductor nanowire laser and
nanowire waveguide electro-optic modulators,” Appl. Phys. Lett. 87, 151103-1 - 151103-3
(2005).
265. S. Gradečak, F. Qian, Y. Li, H.-G. Park and C.M. Lieber, “GaN nanowire lasers with low lasing
thresholds,” Appl. Phys. Lett. 87, 173111-1 -173111-3 (2005).
266. R. Agarwal, K. Ladavac, Y. Roichman, G. Yu, C.M. Lieber and D.G. Grier, “Manipulation and
assembly of nanowires with holographic optical traps,” Opt. Express 13, 8906-8912 (2005).
267. F. Qian, S. Gradečak, Y. Li, C. Wen and C.M. Lieber, “Core/multishell nanowire
heterostructures as multicolor, high-efficiency light-emitting diodes,” Nano Lett. 5, 2287-2291
(2005).
268. C. Yang, Z. Zhong and C.M. Lieber, “Encoding electronic properties by synthesis of axial
modulation doped silicon nanowires,” Science 310, 1304-1307 (2005).
269. C.J. Barrelet, J. Bao, M. Loncar, H.-G. Park, F. Capasso and C.M. Lieber, “Hybrid singlenanowire photonic crystal and microresonator structures,” Nano Lett. 6, 11-15 (2006).
22
270. J.E. Savage, E. Rachlin, A. DeHon, C.M. Lieber and Y. Wu, “Radial addressing of nanowires,”
J. Emerg. Technol. Comput. Syst. 2, 129-154 (2006).
271. O. Hayden, R. Agarwal and C.M. Lieber, “Nanoscale avalanche photodiodes for highly-sensitive
and spatially-resolved photon detection,” Nat. Mater. 5, 352-356 (2006).
272. J. Xiang, W. Lu, Y. Hu, Y. Wu, H. Yan and C.M. Lieber, “Ge/Si nanowire heterostructures as
high-performance field-effect transistors,” Nature 441, 489-493 (2006).
273. F. Patolsky, G. Zheng and C.M. Lieber, “Nanowire sensors for medicine and the life sciences,”
Nanomedicine 1, 51-65 (2006).
274. Y. Li, J. Xiang, F. Qian, S. Gradečak, Y. Wu, H. Yan, D.A. Blom and C.M. Lieber, “Dopant-free
GaN/AlN/AlGaN radial nanowire heterostructures as high electron mobility transistors,” Nano
Lett. 6, 1468-1473 (2006).
275. F. Patolsky, G. Zheng and C.M. Lieber, “Nanowire-based biosensors,” Anal. Chem. 78, 4260-
4269 (2006).
276. F. Patolsky, B.P. Timko, G. Yu, Y. Fang, A.B. Greytak, G. Zheng and C.M. Lieber, “Detection,
stimulation, and inhibition of neuronal signals with high-density nanowire transistor arrays,”
Science 313, 1100-1104 (2006).
277. Y. Li, F. Qian, J. Xiang and C.M. Lieber, “Nanowire electronic and optoelectronic devices,”
Materials Today 9, 18-27 (2006).
278. R. Agarwal and C.M. Lieber, “Semiconductor nanowires: optics and optoelectronics,” Appl.
Phys. A: Mater. Sci. Proc. 85, 209-215 (2006).
279. F. Patolsky, G. Zheng and C.M. Lieber, “Fabrication of silicon nanowire devices for
ultrasensitive, label-free, real-time detection of biological and chemical species,” Nat. Protocols
1, 1711-1724 (2006).
280. W. Lu and C.M. Lieber, “Semiconductor nanowires,” J. Phys. D: Appl. Phys. 39, R387-R406
(2006).
281. C. Yang, C.J. Barrelet, F. Capasso and C.M. Lieber, “Single p-type/intrinsic/n-type silicon
nanowires as nanoscale avalanche photodetectors,” Nano Lett. 6, 2929-2934 (2006).
282. J. Xiang, A. Vidan, M. Tinkham, R.M. Westervelt and C.M. Lieber, “Ge/Si nanowire
mesoscopic Josephson junctions,” Nat. Nanotechnol. 1, 208-213 (2006).
283. C.M. Lieber and Z.L. Wang, “Functional nanowires,” MRS Bull. 32, 99-104 (2007).
284. F. Patolsky, B.P. Timko, G. Zheng and C.M. Lieber, “Nanowire-based nanoelectronic devices in
the life sciences,” MRS Bull. 32, 142-149 (2007).
23
285. G. Liang, J. Xiang, N. Kharche, G. Klimeck, C.M. Lieber and M. Lundstrom, “Performance
analysis of a Ge/Si core/shell nanowire field-effect transistor,” Nano Lett. 7, 642-646 (2007).
286. A. Javey, S. Nam, R.S. Friedman, H. Yan and C.M. Lieber, “Layer-by-layer assembly of
nanowires for three-dimensional, multifunctional electronics,” Nano Lett. 7, 773-777 (2007).
287. G. Yu, A. Cao and C.M. Lieber, “Large-area blown bubble films of aligned nanowires and
carbon nanotubes,” Nat. Nanotechnol. 2, 372-377 (2007).
288. C.M. Lieber, “The incredible shrinking circuit,” Sci. Am. Special Ed. 17, 64-71 (2007).
289. X. Jiang, Q. Xiong, S. Nam, F. Qian, Y. Li and C.M. Lieber, “InAs/InP radial nanowire
heterostructures as high electron mobility devices,” Nano Lett. 7, 3214-3218 (2007).
290. Y. Hu, H.O.H. Churchill, D.J. Reilly, J. Xiang, C.M. Lieber and C.M. Marcus, “A Ge/Si
heterostructure nanowire-based double quantum dot with integrated charge sensor,” Nat.
Nanotechnol. 2, 622-625 (2007).
291. B. Tian, X. Zheng, T.J. Kempa, Y. Fang, N. Yu, G. Yu, J. Huang and C.M. Lieber, “Coaxial
silicon nanowires as solar cells and nanoelectronic power sources,” Nature 449, 885-890 (2007).
292. W. Lu and C.M. Lieber, “Nanoelectronics from the bottom up,” Nat. Mater. 6, 841-850 (2007).
293. O. Hayden, G. Zheng, P. Agarwal and C.M. Lieber, “Visualization of carrier depletion in
semiconducting nanowires,” Small 3, 2048-2052 (2007).
294. Z. Zhong, C. Yang and C.M. Lieber, “Silicon nanowires and nanowire heterostructures,”
Nanosilicon 176-216 (ed. V. Kumar, Elsevier, 2008).
295. A. Noy, D.V. Vezenov and C.M. Lieber, “Chemical force microscopy nanoscale probing of
fundamental chemical interactions,” Handbook of Molecular Force Spectroscopy 97-122 (ed. A.
Noy, Springer, 2008).
296. D.V. Vezenov, A. Noy and C.M. Lieber, “Chemical force microscopy: Force spectroscopy and
imaging of complex interactions in molecular assemblies,” Handbook of Molecular Force
Spectroscopy 123-141 (ed. A. Noy, Springer, 2008).
297. Y. Dong, G. Yu, M.C. McAlpine, W. Lu and C.M. Lieber, “Si/a-Si Core/Shell Nanowires as
Nonvolatile Crossbar Switches,” Nano Lett. 8, 386-391 (2008).
298. G. Yu, X. Li, C.M. Lieber and A. Cao, “Nanomaterial-incorporated blown bubble films for
large-area, aligned nanostructures,” J. Mater. Chem. 18, 728-734 (2008).
299. Y. Hu, J. Xiang, G. Liang, H. Yan and C.M. Lieber, “Sub-100 nanometer channel length Ge/Si
nanowire transistors with potential for 2 THz switching speed,” Nano Lett. 8, 925-930 (2008).
300. C. Wang, Y. Hu, C.M. Lieber and S. Sun, “Ultrathin Au nanowires and their transport
properties,” J. Am. Chem. Soc. 130, 8902-8903 (2008).
24
301. W.I. Park, G. Zheng, X. Jiang, B. Tian and C.M. Lieber, “Controlled synthesis of millimeterlong silicon nanowires with uniform electronic properties,” Nano Lett. 8, 3004-3009 (2008).
302. F. Qian, Y. Li, S. Gradečak, H.-G. Park, Y. Dong, Y. Ding, Z.L. Wang and C.M. Lieber, “Multiquantum-well nanowire heterostructures for wavelength-controlled lasers,” Nat. Mater. 7, 701-
706 (2008).
303. H.-G. Park, C.J. Barrelet, Y. Wu, B. Tian, F. Qian and C.M. Lieber, “A wavelength-selective
photonic-crystal waveguide coupled to a nanowire light source,” Nat. Photonics 2, 622-626
(2008).
304. T.J. Kempa, B. Tian, D.R. Kim, J. Hu, X. Zheng and C.M. Lieber, “Single and tandem axial p-in nanowire photovoltaic devices,” Nano Lett. 8, 3456-3460 (2008).
305. S. Roddaro, A. Fuhrer, P. Brusheim, C. Fasth, H.Q. Xu, L. Samuelson, J. Xiang and C.M.
Lieber, “Spin states of holes in Ge/Si nanowire quantum dots,” Phys. Rev. Lett. 101, 186802-1 –
186802-4 (2008).
306. W. Lu, P. Xie and C.M. Lieber, “Nanowire transistor performance limits and applications,” IEEE
Trans. Electron Dev. 55, 2859-2876 (2008).
307. B. Tian, T.J. Kempa and C.M. Lieber, “Single nanowire photovoltaics,” Chem. Soc. Rev. 38, 16-
24 (2009).
308. B.P. Timko, T. Cohen-Karni, G. Yu, Q. Qing, B. Tian and C.M. Lieber, “Electrical recording
from hearts with flexible nanowire device arrays,” Nano Lett. 9, 914-918 (2009).
309. F.A. Zwanenburg, C.E.W.M. van Rijmenam, Y. Fang, C.M. Lieber and L.P. Kouwenhoven,
“Spin states of the first four holes in a silicon nanowire quantum dot,” Nano Lett. 9, 1071-1079
(2009).
310. T. Cohen-Karni, B.P. Timko, L.E. Weiss and C.M. Lieber, “Flexible electrical recording from
cells using nanowire transistor arrays,” Proc. Natl. Acad. Sci. USA 106, 7309-7313 (2009).
311. Y. Dong, B. Tian, T. Kempa and C.M. Lieber, “Coaxial group III-nitride nanowire
photovoltaics,” Nano Lett. 9, 2183-2187 (2009).
312. S. Vandenbrouck, K. Madjour, D. Théron, Y.J. Dong, Y. Li, C.M. Lieber and C. Gaquiere, “12
GHz FMAX GaN/AlN/AlGaN nanowire MISFET,” IEEE Electron Dev. Lett. 30, 322-324 (2009).
313. F.A. Zwanenburg, A.A. van Loon, G.A. Steele, C.E.W.M. van Rijmenam, T. Balder, L.P.
Kouwenhoven, Y. Fang and C.M. Lieber, “Ultra-small silicon quantum dots,” J. Appl. Phys. 105,
124314-1 (2009).
314. P. Xie, Y. Hu, Y. Fang, J.Huang and C.M. Lieber, “Diameter-dependent dopant location in
silicon and germanium nanowires,” Proc. Natl. Acad. Sci. USA 106, 15254-15258 (2009).
25
315. S.K. Lim, M. Brewster, F. Qian, Y. Li, C.M. Lieber and S. Gradečak, “Direct correlation
between structural and optical properties of III-V nitride nanowire heterostructures with
nanoscale resolution,” Nano Lett. 9, 3940-3944 (2009).
316. B. Tian, P. Xie, T.J. Kempa, D.C. Bell and C.M. Lieber, “Single crystalline kinked
semiconductor nanowire superstructures,” Nat. Nanotechnol., 4, 824-829 (2009).
317. S.W. Nam, X. Jiang, Q. Xiong, D. Ham and C.M. Lieber, “Vertically integrated, threedimensional nanowire complementary metal-oxide-semiconductor circuits,” Proc. Natl. Acad.
Sci. USA, 106, 21035-21038 (2009).
318. N.A. Kotov, J.O. Winter, I.P. Clements, E. Jan, B.P. Timko, S. Campidelli, S. Pathak, A.
Mazzatenta, C.M. Lieber, M. Prato, R.V. Bellamkonda, G.A. Silva, N.W.S. Kam, F. Patolsky
and L. Ballerini, “Nanomaterials for neural interfaces,” Adv. Mater. 21, 3970-4004 (2009).
319. X.P. Gao, G. Zheng and C.M. Lieber, “Subthreshold regime has the optimal sensitivity for
nanowire FET biosensors,” Nano Lett. 10, 547-552 (2010).
320. Q. Qing, S.K. Pal, B. Tian, X. Duan, B.P. Timko, T. Cohen-Karni, V.N. Murthy and C.M.
Lieber, “Nanowire transistor arrays for mapping neural circuits in acute brain slices,” Proc. Natl.
Acad. Sci. USA 107, 1882-1887 (2010).
321. T. Cohen-Karni, Q. Qing, Q. Li, Y. Fang and C.M. Lieber, “Graphene and nanowire transistors
for cellular interfaces and electrical recording,” Nano Lett. 10, 1098-1102 (2010).
322. B.P. Timko, T. Cohen-Karni, Q. Qing, B. Tian and C.M. Lieber, “Design and implementation of
functional nanoelectronic interfaces with biomolecules, cells and tissue using nanowire device
arrays,” IEEE Trans. Nanotechnol. 9, 269-280 (2010).
323. G. Zheng, X. Gao and C.M. Lieber, “Frequency domain detection of biomolecules using silicon
nanowire biosensors,” Nano Lett. 10, 3179-3183 (2010).
324. B. Tian, T. Cohen-Karni, Q. Qing, X. Duan, P. Xie and C.M. Lieber, “Three-dimensional,
flexible nanoscale field effect transistors as localized bioprobes,” Science 329, 831-834 (2010).
325. S. Kwon, J. Kang, C. Seassal, S. Kim, P. Regreny, Y. Lee, C.M. Lieber and H. Park,
“Subwavelength plasmonic lasing from a semiconductor nanodisk with silver nanopan cavity,”
Nano Lett. 10, 3679-3683 (2010).
326. X. Jiang, J. Hu, L.A. Fitzgerald, J.C. Biffinger, P. Xie, B. R. Ringeisen and C.M. Lieber,
“Probing electron transfer mechanisms in Shewanella oneidensis MR-1 using a nanoelectrode
platform and single cell imaging,” Proc. Natl. Acad. Sci. USA 107, 16806-16810 (2010).
327. G. Yu and C.M. Lieber, “Assembly and integration of semiconductor nanowires for functional
nanosystems,” Pure Appl. Chem. 82, 2295-2314 (2010).
328. H. Yan, H.S. Choe, S.W. Nam, Y. Hu, S. Das, J.F. Klemic, J.C. Ellenbogen and C.M. Lieber,
“Programmable nanowire circuits for nanoprocessors,” Nature 470, 240-244 (2011).
26
329. X. Jiang, B. Tian, J. Xiang, F. Qian, G. Zheng, H. Wang, L. Mai and C.M. Lieber, “Rational
growth of branched nanowire heterostructures with synthetically encoded properties and
function,” Proc. Natl. Acad. Sci. USA 108, 12212-12216 (2011).
330. B. Tian and C.M. Lieber, “Design, synthesis, and characterization of novel nanowire structures
for photovoltaics and intracellular probes,” Pure Appl. Chem. 83, 2153-2169 (2011).
331. T. Cohen-Karni, B. Tian and C.M. Lieber, “Electrical recording from cardiac cells and tissue
using nanowire transistors,” Nanomedicine and the Cardiovascular System (eds. R.J. Hunter and
V.R. Preedy), Science Publishers, 2011.
332. C.M. Lieber, “Semiconductor nanowires: A platform for nanoscience and nanotechnology,” MRS
Bull. 36, 1052-1063 (2011).
333. G.F. Zheng and C.M. Lieber, “Nanowire biosensors for label-free, real-time, ultrasensitive
protein detection,” Nanoproteomics Methods and Protocols (eds. S.A. Toms and R.J. Wells),
Humana Press, 2011.
334. Y. Hu, F. Kuemmeth, C.M. Lieber and C.M. Marcus, “Hole spin relaxation in Ge/Si core-shell
nanowire qubits,” Nat. Nanotechnol. 7, 47-50 (2012).
335. T.J. Kempa, J.F. Cahoon, S.-K. Kim, R.W. Day, D.C. Bell, H.-G. Park and C.M. Lieber,
"Coaxial multishell nanowires with high-quality electronic interfaces and tunable optical cavities
for ultrathin photovoltaics," Proc. Natl. Acad. Sci. USA 109, 1407-1412 (2012).
336. J.-U. Park, S. Nam, M.-S. Lee and C.M. Lieber, “Synthesis of monolithic graphene-graphite
integrated electronics,” Nat. Mater. 11, 120-125 (2012).
337. P. Xie, Q. Xiong, Y. Fang, Q. Qing and C.M. Lieber, “Local electrical potential detection of
DNA by nanowire-nanopore sensors,” Nat. Nanotechnol. 7, 119-125 (2012).
338. X. Duan, R. Gao, P. Xie, T. Cohen-Karni, Q. Qing, H.S. Choe, B. Tian, X. Jiang and C.M.
Lieber, “Intracellular recordings of action potentials by an extracellular nanoscale field-effect
transistor,” Nat. Nanotechnol. 7, 174-179 (2012).
339. Z. Jiang, Q. Qing, P. Xie, R. Gao and C.M. Lieber, “Kinked p-n junction nanowire probes for
high spatial resolution sensing and intracellular recording,” Nano Lett. 12, 1711-1716 (2012).
340. T. Cohen-Karni, D. Casanova, J. Cahoon, Q. Qing, D. Bell and C.M. Lieber, “Syntheticallyencoded ultrashort-channel nanowire transistors for fast, point-like cellular signal detection,”
Nano Lett. 12, 2639-2644 (2012).
341. R. Gao, S. Strehle, B. Tian, T. Cohen-Karni, P. Xie, X. Duan, Q. Qing and C.M. Lieber,
“Outside looking in: Nanotube transistor intracellular sensors,” Nano Lett. 12, 3329-3333 (2012).
342. S.K. Kim, R.W. Day, J. Cahoon, T. Kempa, K. Song, H.-G. Park and C.M. Lieber, “Tuning light
absorption in core/shell silicon nanowire photovoltaic devices through morphological design,”
Nano Lett. 12, 4971-4976 (2012).
27
343. B. Tian, J. Liu, T. Dvir, L. Jin, J.H. Tsui, Q. Qing, Z. Suo, R. Langer, D.S. Kohane and C.M.
Lieber, “Macroporous nanowire nanoelectronic scaffolds for synthetic tissues,” Nat. Mater. 11,
986-994 (2012).
344. E.J.H. Lee, X. Jiang, R. Aguado, G. Katsaros, C.M. Lieber and S. De Franceschi, “Zero-bias
anomaly in a nanowire quantum dot coupled to superconductors,” Phys. Rev. Lett. 109, 186802-
1-5 (2012).
345. L. Xu, Z. Jiang, Q. Qing, L. Mai, Q. Zhang and C.M. Lieber, “Design and synthesis of diverse
functional kinked nanowire structures for nanoelectronic bioprobes,” Nano Lett. 13, 746-751
(2013).
346. T. Kempa, R. Day, S. Kim, H. Park and C.M. Lieber, “Semiconductor nanowires: A platform for
exploring limits and concepts for nano-enabled solar cells,” Energy Environ. Sci. 6, 719-733
(2013).
347. J. Liu, C. Xie, X. Dai, L. Jin, W. Zhou and C.M. Lieber, “Multifunctional three-dimensional
macroporous nanoelectronic networks for smart materials,” Proc. Natl. Acad. Sci. USA. 110,
6694-6699 (2013).
348. T. Cohen-Karni and C.M. Lieber, “Nanowire nanoelectronics: Building interfaces with tissue
and cells at the natural scale of biology,” Pure and Appl. Chem. 85, 883-901 (2013).
349. J. Yao, H. Yan and C.M. Lieber, “A nanoscale combing technique for the large-scale assembly
of highly aligned nanowires,” Nat. Nanotechnol. 8, 329-335 (2013).
350. B. Tian and C.M. Lieber, “Synthetic nanoelectronic probes for biological cells and tissues,”
Annu. Rev. Anal. Chem. 6, 31-51 (2013).
351. X. Duan, T.-M. Fu, J. Liu and C.M. Lieber, “Nanoelectronics-biology frontier: From nanoscopic
probes for action potential recording in live cells to three-dimensional cyborg tissues,” Nano
Today 8, 351-373 (2013).
352. X. Duan and C.M. Lieber, “Nanoelectronics meets biology: From new nanoscale devices for
live-cell recording to 3D innervated tissues,” Chem. Asian J. 8, 2304-2314 (2013).
353. X. Jiang, J. Hu, E.R. Petersen, L.A. Fitzgerald, C.S. Jackan, A.M. Lieber, B.R. Ringeisen, C.M.
Lieber and J.C. Biffinger, “Probing single- to multi-cell level charge transport in Geobacter
sulfurreducens DL-1,” Nat. Commun. 4, 2751 (2013).
354. T. Kempa, S.-K. Kim, R. Day, H.-G. Park, D. Nocera and C.M. Lieber, “Facet-selective growth
on nanowires yields multi-component nanostructures and photonic devices,” J. Am. Chem. Soc.
135, 18354-18357 (2013).
355. T. Kempa and C.M. Lieber, “Semiconductor nanowire solar cells: synthetic advances and
tunable properties,” Pure Appl. Chem. 86, 13-26 (2014).
28
356. E. Lee, X. Jiang, M. Houzet, R. Aguado, C.M. Lieber, and S. De Franceschi, “Spin-resolved
Andreev levels and parity crossings in hybrid superconductor-semiconductor nanostructures,”
Nat. Nanotechnol. 9, 79-84 (2014).
357. Q. Qing, Z. Jiang, L. Xu, R. Gao, L. Mai and C.M. Lieber, “Free-standing kinked nanowire
transistor probes for targeted intracellular recording in three dimensions,” Nat. Nanotechnol. 9,
142-147 (2014).
358. T.-M. Fu, X. Duan, Z. Jiang, X. Dai, P. Xie, Z. Cheng and C.M. Lieber, “Sub-10 nanometer
intracellular bioelectronic probes from nanowire-nanotube heterostructures,” Proc. Natl. Acad.
Sci. USA 111, 1259-1264 (2014).
359. J. Yao. H. Yan, S. Das, J. Klemic, J. Ellenbogen and C.M. Lieber, “Nanowire nanocomputer as a
finite-state machine,” Proc. Natl. Acad. Sci. USA 111, 2431-2435 (2014).
360. W. Zhou, X. Dai, T.-M. Fu, C. Xie, J. Liu and C.M. Lieber, “Long term stability of nanowire
nanoelectronics in physiological environments,” Nano Lett. 14, 1614-1619 (2014).
361. S.-K. Kim, K.-D. Song, T. Kempa, R. Day, C.M. Lieber and H.-G. Park, “Design of nanowire
optical cavities as efficient photon absorbers,” ACS Nano 8, 3707-3714 (2014).
362. A. Higginbotham, T. Larsen, J. Yao, H. Yan, C.M. Lieber, C. Marcus and F. Kuemmeth, “Hole
spin coherence in a Ge/Si heterostructure nanowire,” Nano Lett. 14, 3582-3586 (2014).
363. A. Higginbotham, F. Kuemmeth, T. Larsen, J. Yao, H. Yan, C.M. Lieber and C. Marcus,
“Antilocalization of coulomb blockade in Ge/Si nanowire,” Phys. Rev. Lett. 112, 216806 (2014).
364. W. Shim, J. Yao and C.M. Lieber, “Programmable resistive-switch nanowire transistor logic
circuits,” Nano Lett. 14, 5430-5436 (2014).
365. Q. Zhang, G. Li, X. Liu, F. Qian, Y. Li, T.C. Sum, C.M. Lieber and Q. Xiong, “A room
temperature low-threshold ultraviolet plasmonic nanolaser,” Nat. Commun. 5, 5953 (2014).
366. X. Jiang, J. Hu, A. Lieber, C. Jackan, J. Biffinger, L. Fitzgerald, B. Ringeisen and C.M. Lieber,
“Nanoparticle facilitated extracellular electron transfer in microbial fuel cells,” Nano Lett. 14,
6737-6742 (2014).
367. X. Duan and C.M. Lieber, “Nanoscience and the nano-bioelectronics frontier,” Nano Research 8,
1-22 (2015).
368. L. Chen, W. Lu and C.M. Lieber, “Semiconductor nanowire growth and integration,” in
Semiconductor nanowires: From next-generation electronics to sustainable energy, Ed. W. Lu
and J. Xiang, Royal Society of Chemistry, 2015, 1-53.
369. N. Gao, W. Zhou, X. Jiang, G. Hong, T.-M. Fu and C.M. Lieber, “General strategy for
biodetection in high ionic strength solutions using transistor-based nanoelectronic sensors,”
Nano Lett. 15, 2143-2148 (2015).
29
370. R. Day, M. Mankin, R. Gao, Y.-S. No, S.-K. Kim, D. Bell, H.-G. Park and C.M. Lieber,
“Plateau-Rayleigh crystal growth of periodic shells on one-dimensional substrates,” Nat.
Nanotechnol. 10, 345-352 (2015).
371. P. Kruskal, Z. Jiang, T. Gao and C.M. Lieber, “Beyond the patch clamp: Nanotechnologies for
intracellular recording,” Neuron 86, 21-24 (2015).
372. J. Liu, T.-M. Fu, Z. Cheng, G. Hong, T. Zhou, L. Jin, M. Duvvuri, Z. Jiang, P. Kruskal, C. Xie,
Z. Suo, Y. Fang and C.M. Lieber, “Syringe-injectable electronics,” Nat. Nanotechnol. 10, 629-
636 (2015).
373. M. Mankin, R. Day, R. Gao, Y.-S. No, S.-K. Kim, A. McClelland, D. Bell, H.-G. Park and C.M.
Lieber, “Facet-selective epitaxy of compound semiconductors on faceted silicon nanowires,”
Nano Lett. 15, 4776-4782 (2015).
374. G. Hong, T.-M. Fu, T. Zhou, T. Schuhmann, J. Huang and C.M. Lieber, “Syringe injectable
electronics: Precise targeted delivery with quantitative input/output connectivity,” Nano Lett. 15,
6979-6984 (2015).
375. A.P. Alivisatos, H. Tierney, P. Weiss and C.M. Lieber, “ACS Nano and Nano Letters, partners in
leading nanoscience and nanotechnology,” Nano Lett. 15, 4845-4845 (2015).
376. T.J. Kempa, D.K. Bediako, E.C. Jones, C.M. Lieber and D.G. Nocera, “Facile, rapid, and largearea periodic patterning of semiconductor substrates with submicron inorganic structures,” J.
Am. Chem. Soc. 137, 3739-3742 (2015).
377. C. Xie, J. Liu, T.-M. Fu, X. Dai, W. Zhou and C.M. Lieber, “Three-dimensional macroporous
nanoelectronic networks as minimally invasive brain probes,” Nat. Mater. 14, 1286-1292 (2015).
378. A. Zhang and C.M. Lieber, “Nano-bioelectronics,” Chem. Rev. 116, 215-257 (2016).
379. J.-H. Lee, A. Zhang, S. You and C.M. Lieber, “Spontaneous internalization of cell penetrating
peptide-modified nanowires into primary neurons,” Nano Lett. 16, 1509-1513 (2016).
380. R. Day, M. Mankin and C.M. Lieber, “Plateau-Rayleigh crystal growth of nanowire
heterostructures: Strain-modified surface chemistry and morphological control in one, two and
three dimensions,” Nano Lett. 16, 2830-2836 (2016).
381. Y. Zhao, J. Yao, L. Xu, M. Mankin, Y. Zhu, H. Wu, L. Mai, Q. Zhang and C.M. Lieber, “Shapecontrolled deterministic assembly of nanowires,” Nano Lett. 16, 2644-2650 (2016).
382. Y. Brovman, J. Small, Y. Hu, Y. Fang, C.M. Lieber and P. Kim, “Electric field effect
thermoelectric transport in individual silicon and germanium/silicon nanowires,” J. Appl. Phys.
119, 234304 (2016).
383. Y.-S. No, R. Gao, M. Mankin, R. Day, H.-G. Park and C.M. Lieber, “Encoding active device
elements at nanowire tips,” Nano Lett. 16, 4713-4719 (2016).
30
384. X. Dai, W. Zhou, T. Gao, J. Liu and C.M. Lieber, “Three-dimensional mapping and regulation of
action potential propagation in nanoelectronics-innervated tissues,” Nat. Nanotechnol. 11, 776-
782 (2016).
385. A. Zhang, G. Zheng and C.M. Lieber, Nanowires: Building blocks for nanoscience and
nanotechnology, Springer 2016.
386. T.-M. Fu, G. Hong, T. Zhou, T. Schuhmann, R.D. Viveros and C.M. Lieber, “Stable long-term
chronic brain mapping at the single neuron level,” Nat. Methods 13, 875-882 (2016).
387. N. Gao, T. Gao, X. Yang, X. Dai, W. Zhou, A. Zhang and C.M. Lieber, “Specific detection of
biomolecules in physiological solutions using graphene transistor biosensors,” Proc. Natl. Acad.
Sci. USA 113, 14633-14638 (2016).
388. W. Zhou, X. Dai and C.M. Lieber, “Advances in nanowire bioelectronics,” Rep. Prog. Phys. 80,
016701 (2017).
389. E.J.H. Lee, X. Jiang, R. Zitko, R. Aguado, C.M. Lieber and S. De Franceschi, “Scaling of subgap excitations in a superconductor-semiconductor nanowire quantum dot,” Phys. Rev. B 95,
180502(R) (2017).
390. T. Zhou, G. Hong, T.-M. Fu, X. Yang, T.G. Schuhmann, R.D. Viveros and C.M. Lieber,
“Syringe-injectable mesh electronics integrate seamlessly with minimal chronic immune
response in the brain,” Proc. Natl. Acad. Sci. USA 114, 5894-5899 (2017).
391. P.E. Sheehan and C.M. Lieber, “Friction between van der Waals solids during lattice directed
sliding,” Nano Lett. 17, 4116-4121 (2017).
392. T. Ozel, B.A. Zhang, R. Gao, R.W. Day, C.M. Lieber and D.G. Nocera, “Electrochemical
deposition of conformal and functional layers on high aspect ratio silicon micro/nanowires,”
Nano Lett. 17, 4502-4507 (2017).
393. R. Wang, R.S. Deacon, J. Yao, C.M. Lieber and K. Ishibashi, “Electrical modulation of weakantilocalization and spin orbit interaction in dual gated Ge/Si core/shell nanowires,” Semicond.
Sci. Tech. 32, 094002 (11 pp) (2017).
394. T.G. Schuhmann, J. Yao, G. Hong, T.-M. Fu and C.M. Lieber, “Syringe-injectable electronics
with a plug-and-play input/output interface,” Nano Lett. 17, 5836-5842 (2017).
395. T.-M. Fu, G. Hong, R.D. Viveros, T. Zhou and C.M. Lieber, “Highly scalable multichannel mesh
electronics for stable chronic brain electrophysiology,” Proc. Natl. Acad. Sci. USA 114, E10046-
E10055 (2017).
396. G. Hong, X. Yang, T. Zhou and C.M. Lieber, “Mesh electronics: a new paradigm for tissue-like
brain probes,” Curr. Opin. Neurobiol. 50, 33-41 (2018).
397. X. Dai, G. Hong, T. Gao and C.M. Lieber, “Mesh nanoelectronics: seamless integration of
electronics with tissues,” Acc. Chem. Res. 51, 309-318 (2018).
31
398. G. Hong, R.D. Viveros, T.J. Zwang, X. Yang and C.M. Lieber, “Tissue-like neural probes for
understanding and modulating the brain,” Biochemistry 57, 3995-4004 (2018).
399. G. Hong, T.-M. Fu, M. Qian, R.D. Viveros, X. Yang, T. Zhou, J.M. Lee, H.-G. Park, J.R. Sanes
and C.M. Lieber, “A method for single-neuron chronic recording from the retina in awake mice,”
Science 360, 1447-1451 (2018).
400. T.G. Schuhmann, T. Zhou, G. Hong, J.M. Lee, T.-M. Fu, H.-G. Park and C.M. Lieber, “Syringeinjectable mesh electronics for stable chronic rodent electrophysiology,” J. Vis. Exp. 137, e58003
(2018).
401. J. Sun, R.S. Deacon, R. Wang, J. Yao, C.M. Lieber and K. Ishibashi, “Helical hole state in
multiple conduction modes in Ge/Si core/shell nanowire,” Nano Lett. 18, 6144-6149 (2018).
402. R. Wang, R.S. Deacon, J. Sun, J. Yao, C.M. Lieber and K. Ishibashi, “Gate tunable hole charge
qubit formed in a Ge/Si nanowire double quantum dot coupled to microwave photons,” Nano
Lett. 19, 1052-1060 (2019).
403. X. Yang, T. Zhou, T.J. Zwang, G. Hong, Y. Zhao, R.D. Viveros, T.-M. Fu, T. Gao and C.M.
Lieber, “Bioinspired neuron-like electronics,” Nat. Mater. 18, 510-517 (2019).
404. G. Hong and C.M. Lieber, “Novel electrode technologies for neural recordings,” Nat. Rev.
Neurosci. 20, 330-345 (2019).
405. B. Tian and C.M. Lieber, "Nanowired bioelectric interfaces," Chem. Rev. 119, 9136−9152
(2019).
406. R.D. Viveros, T. Zhou, G. Hong, T.-M. Fu, H.Y.G. Lin and C.M. Lieber, “Advanced one- and
two-dimensional mesh designs for injectable electronics,” Nano Lett. 19, 4180-4187 (2019).
407. Y. Zhao, S. You, A. Zhang, J.-H. Lee, J.L. Huang and C.M. Lieber, “Scalable ultrasmall threedimensional nanowire transistor probes for intracellular recording,” Nat. Nanotechnol. 14, 783-
790 (2019).
408. J.M. Lee, G. Hong, D. Lin, T.G. Schuhmann, A.T. Sullivan, R.D. Viveros, H.-G. Park and C.M.
Lieber, “Nano-enabled direct contact interfacing of syringe-injectable mesh electronics,” Nano
Lett. 19, 5818-5826 (2019).
409. S.R. Patel and C.M. Lieber, “Precision electronic medicine in the brain,” Nat. Biotechnol. 37,
1007-1012 (2019).
410. N.M. Tran, K. Shekhar, I.E. Whitney, A. Jacobi, I. Benhar, G. Hong, W. Yan, X. Adiconis, M.E.
Arnold, J.M. Lee, J.Z. Levin, D. Lin, C. Wang, C.M. Lieber, A. Regev, Z. He and J.R. Sanes,
“Single-cell profiles of retinal ganglion cells differing in resilience to injury reveal
neuroprotective genes,” Neuron 86, 21-24 (2019).
411. M. Sistani, J. Delaforce, R. B. G. Kramer, N. Roch, M. A. Luong, M.I. den Hertog, E. Robin, J.
Smoliner, J. Yao, C.M. Lieber, C. Naud, A. Lugstein and O. Buisson, “Highly transparent
32
contacts to the 1D hole gas in ultrascaled Ge/Si core/shell nanowires,” ACS Nano 13,
14145−14151 (2019).
412. A. Zhang, Y. Zhao, S. You and C.M. Lieber, “Nanowire probes could drive high-resolution
brain-machine interfaces,” Nano Today DOI: 10.1016/j.nantod.2019.100821, 9 Dec 2019.
Patents
Lieber’s original work has resulted in more than 100 United States and International patents
issued and pending. These breakthroughs have served as the underlying intellectual property for
several small companies, including Nanosys, Inc., Nantero and Vista Therapeutics. Issued and
pending United States patents are as follows:
US Patents Issued
1. C.M. Lieber, Z.J. Zhang and C. Niu, “Covalent Carbon Nitride Material Comprising C2N and
Formation Method,” US Patent 5,840,435 issued 24 November 1998.
2. C.M. Lieber and P. Yang, “Metal Oxide Nanorods,” US Patent 5,897,945 issued 27 April 1999.
3. C.M. Lieber and E. Wong, “Preparation of Carbide Nanorods,” US Patent 5,997,832 issued 7
December 1999.
4. C.M. Lieber and P. Yang, “Method of Producing Metal Oxide Nanorods,” US Patent 6,036,774
issued 14 March 2000.
5. C.M. Lieber, S.S. Wong, A.T. Woolley and E. Joselevich, “Nanometer-Scale Microscopy
Probes,” US Patent 6,159,742 issued 12 December 2000.
6. C.M. Lieber and H. Dai, “Carbide Nanomaterials,” US Patent 6,190,634 issued 20 February
2001.
7. J.H. Hafner, C.L. Cheung and C.M. Lieber, “Fabrication of Nanotube Microscopy Tips,” US
Patent 6,716,409 issued 6 April 2004.
8. C.M. Lieber, J.H. Hafner, C.L. Cheung and P. Kim, “Direct Growth of Nanotubes, and Their Use
in Nanotweezers,” US Patent 6,743,408 issued 1 June 2004.
9. C.M. Lieber, T. Rueckes, E. Joselevich and K. Kim, “Nanoscopic Wire-Based Devices and
Arrays,” US Patent 6,781,166 issued 24 August 2004.
10. A. DeHon, C.M. Lieber, P.D. Lincoln and J.E. Savage, “Stochastic Assembly of Sublithographic
Nanoscale Interfaces,” US Patent 6,900,479 issued 31 May 2005.
11. A. DeHon, C.M. Lieber, P.D. Lincoln and J.E. Savage, “Sublithographic Nanoscale Memory
Architecture,” US Patent 6,963,077 issued 8 November 2005.
33
12. A. DeHon and C.M. Lieber, “Array-Based Architecture for Molecular Electronics,” US Patent
7,073,157 issued 4 July 2006.
13. C.M. Lieber, H. Park, Q. Wei, Y. Cui and W. Liang, “Nanosensors,” US Patent 7,129,554 issued
31 October 2006.
14. C.M. Lieber, T. Rueckes, E. Joselevich and K. Kim, “Methods of Forming Nanoscopic WireBased Devices and Arrays,” US Patent 7,172,953 issued 6 February 2007.
15. C.M. Lieber, Y. Cui, X. Duan and Y. Huang, “Doped Elongated Semiconductors, Growing Such
Semiconductors, Devices Including Such Semiconductors and Fabricating Such Devices,” US
Patent 7,211,464 issued 1 May 2007.
16. C.M. Lieber, X. Duan, Y. Huang and R. Agarwal, “Nanoscale Coherent Optical Components,”
US Patent 7,254,151 issued 7 August 2007.
17. C.M. Lieber, H. Park, Q. Wei, Y. Cui and W. Liang, “Nanosensors,” US Patent 7,256,466 issued
14 August 2007.
18. A. DeHon, M.J. Wilson and C.M. Lieber, “Nanoscale Wire-Based Sublithographic
Programmable Logic Arrays,” US Patent 7,274,208 issued 25 September 2007.
19. C.M. Lieber, X. Duan, Y. Cui, Y. Huang, M. Gudiksen, L.J. Lauhon, J. Wang, H. Park, Q. Wei,
W. Liang, D.C. Smith, D. Wang and Z. Zhong, “Nanoscale Wires and Related Devices,” US
Patent 7,301,199 issued 27 November 2007.
20. C.M. Lieber, H. Park, Q. Wei, Y. Cui and W. Liang, “Nanosensors,” US Patent 7,385,267 issued
10 June 2008.
21. C.M. Lieber, T. Rueckes, E. Joselevich and K. Kim, “Methods of Forming Nanoscopic WireBased Devices and Arrays,” US Patent 7,399,691 issued 15 July 2008.
22. C.M. Lieber, Y. Cui, X. Duan and Y. Huang, “Doped Elongated Semiconductors, Growing Such
Semiconductors, Devices Including Such Semiconductors and Fabricating Such Devices,” US
Patent 7,476,596 issued 13 January 2009.
23. DeHon and C.M. Lieber, “Array-Based Architecture for Molecular Electronics,” US Patent
7,500,213 issued 3 March 2009.
24. C.M. Lieber, Y. Cui, X. Duan and Y. Huang, “Doped Elongated Semiconductors, Growing Such
Semiconductors, Devices Including Such Semiconductors, and Fabricating Such Devices,” US
Patent 7,595,260 issued 29 September 2009.
25. C.M. Lieber, H. Park, Q. Wei, Y. Cui and W. Liang, “Nanosensors,” US Patent 7,619,290 issued
17 November 2009.
26. C.M. Lieber, Y. Cui, X. Duan and Y. Huang, “Doped Elongated Semiconductors, Growing Such
Semiconductors, Devices Including Such Semiconductors and Fabricating Such Devices,” US
Patent 7,666,708 issued 23 February 2010.
34
27. A. DeHon, C.M. Lieber, P.D. Lincoln and J.E. Savage, “Nanoscale Wire Coding for Stochastic
Assembly,” US Patent 7,692,952 issued 6 April 2010.
28. D.G. Grier, R. Agarwal, G. Yu, C.M. Lieber, K. Ladavac and Y. Roichman, “System and
Method for Processing Nanowires with Holographic Optical Tweezers,” US Patent 7,772,543
issued 10 August 2010.
29. W. Lu, J. Xiang, Y. Wu, B.P. Timko, H. Yan and C.M. Lieber, “Nanowire Heterostructures,” US
Patent 7,858,965 issued 28 December 2010.
30. C.M. Lieber, H. Park, Q. Wei, Y. Cui and W. Liang, “Nanosensors,” US Patent 7,911,009 issued
22 March 2011.
31. C.M. Lieber, Y. Cui, X. Duan and Y. Huang, “Doped Elongated Semiconductors, Growing Such
Semiconductors, Devices Including Such Semiconductors, and Fabricating Such Devices,” US
Patent 7,915,151 issued 28 March 2011.
32. H. Park, C.M. Lieber, J.J. Urban, Q. Gu and W.S. Yun, “Transition Metal Oxide Nanowires,” US
Patent 7,918,935 issued 5 April 2011.
33. C.M. Lieber, B. Tian and X. Jiang, “Branched Nanoscale Wires,” US Patent 8,058,640 issued 15
November 2011.
34. A. DeHon, C.M. Lieber, J.E. Savage and E. Rachlin, “Apparatus, Method and Computer
Program Product Providing Radial Addressing of Nanowires,” US Patent 8,072,005 issued 6
December 2011.
35. C.M. Lieber, Y. Wu and H. Yan, “Nanoscale Wire-Based Data Storage,” US Patent 8,154,002
issued 10 April 2012.
36. C. M. Lieber, Y. Cui, X. Duan and Y. Huang, “Doped Elongated Semiconductors, Growing Such
Semiconductors, Devices Including Such Semiconductors, and Fabricating Such Devices,” US
Patent 8,153,470 issued 10 April 2012.
37. C.M. Lieber, T. Rueckes, E. Joselevich and K. Kim, “Nanoscopic Wire-Based Devices and
Arrays,” US Patent 8,178,907 issued 15 May 2012.
38. C.M. Lieber, F. Patolsky and G. Zheng, “Nanoscale Sensors,” US Patent 8,232,584 issued 31
July 2012.
39. C.M. Lieber, X. Gao and G. Zheng, “High-Sensitivity Nanoscale Wire Sensors,” US Patent
8,575,663 issued 5 November 2013.
40. C.M. Lieber, G. Yu and A. Cao, “Liquid Films Containing Nanostructured Materials,” US Patent
8,586,131 issued 19 Nov 2013.
41. C.M. Lieber, Q. Xiong, P. Xie and Y. Fang, “High-Resolution Molecular Sensor,” US Patent
8,698,481 issued 15 April 2014.
35
42. C.M. Lieber, S. Nam and J.-U. Park, “Controlled Synthesis of Monolithically-Integrated
Graphene Multilayer Structures,” US Patent 9,029,836 issued 12 May 2015.
43. C.M. Lieber, Y. Fang and F. Patolsky, “Nanosensors and Related Technologies,” US Patent
9,102,521 issued 11 August 2015.
44. B. Tian, P. Xie, T.J. Kempa, C.M. Lieber, T. Cohen-Karni, Q. Qing and X. Duan, “Bent
Nanowires and Related Probing of Species,” US Patent 9,297,796 B2 issued 29 March 2016.
45. C.M. Lieber, T. Dvir, D.S. Kohane, R.S. Langer, J. Liu and B. Tian, “Scaffolds Comprising
Nanoelectronic Components, Tissues, and Other Application,” US Patent 9,457,128 issued 4
October 2016.
46. C.M. Lieber, X. Gao, G. Zheng, “High-Sensitivity Nanoscale Wire Sensors,” US Patent
9,535,063 issued 3 January 2017.
47. C.M. Lieber, H.S. Choe and X. Liu, “Nanoscale Field-Effect Transistors for Biomolecular
Sensors and Other Applications,” US Patent 9,541,522 issued 10 January 2017.
48. C.M. Lieber, X. Duan, R. Gao, P. Xie and X. Jiang, “Nanoscale Wires, Nanoscale Wire FET
Devices, and Nanotube-Electronic Hybrid Devices for Sensing and Other Applications,” US
Patent 9,595,685 B2 issued 14 March 2017.
49. C.M. Lieber, R. Gao, X. Duan, S. Strehle, T. Cohen-Karni, B. Tian, P. Xie and Q. Qing,
“Nanoscale Sensors for Intracellular and Other Applications,” US Patent 9,638,717 B2 issued 2
May 2017.
50. C.M. Lieber and P. Xie, “Nanopore Sensing by Local Electrical Potential Measurement,” US
Patent 9,702,849 issued 11 July 2017.
51. C.M. Lieber, B. Tian and J. Liu, “Methods and Systems for Scaffolds Comprising
Nanoelectronic Components,” US Patent 9,786,850 issued 10 October 2017.
52. C.M. Lieber, Y. Fang and F. Patolsky, “Nanosensors and Related Technologies,” US Patent
9,903,862 issued 27 February 2018.
53. C.M. Lieber, S.-K. Kim, R. Day, H.-G. Park and T. Kempa, “Anisotropic Deposition in
Nanoscale Wires,” US Patent 10,049,871 issued 14 August 2018.
54. C.M. Lieber, Q. Xiong, P. Xie and Y. Fang, “High-Resolution Molecular Sensor,” US Patent
10,119,955 issued 6 November 2018.
55. C.M. Lieber, B. Tian and J. Liu, “Methods and Systems for Scaffolds Comprising
Nanoelectronic Components,” US Patent 10,355,229 issued 16 July 2019.
56. C.M. Lieber, J. Liu, B. Tian, T. Dvir, R.S. Langer and D.S. Kohane, “Scaffolds Comprising
Nanoelectronic Components, Tissues, and Other Applications,” US Patent 10,369,255 issued 6
August 2019.
36
57. C.M. Lieber, R. Day, M. Mankin, R. Gao and T.J. Kempa, “Controlled Growth of Nanoscale
Wires,” US Patent 10,435,817 issued 8 October 2019.
58. C.M. Lieber and P. Xie, “Nanopore Sensing by Local Electrical Potential Measurement,” US
Patent 10,436,747 issued 8 October 2019.
US Patents Pending
59. C.M. Lieber, H. Park, Q. Wei, Y. Cui and W. Liang, “Nanosensors,” US Patent Application
13/771,504 filed 20 February 2013.
60. C.M. Lieber, X. Duan, Y. Cui, Y. Huang, M. Gudiksen, L.J. Lauhon, J. Wang, H. Park, Q. Wei,
W. Liang, D.C. Smith, D. Wang and Z. Zhong, “Nanoscale Wires and Related Devices,” US
Patent Application 13/783,915 filed 4 March 2013.
61. C.M. Lieber, T. Rueckes, E. Joselevich and K. Kim, “Nanoscopic Wire-Based Devices, Arrays,
and Methods of Their Manufacture,” US Patent Application 13/900,153 filed 22 May 2013.
62. C.M. Lieber, J. Liu, Z. Cheng, G. Hong, T.-M. Fu and T. Zhou, “Systems and Methods for
Injectable Devices,” US Patent Application 15/301,792 filed 4 October 2016.
63. C.M. Lieber, N. Gao, W. Zhou, X. Jiang, T. Gao and X. Yang, “Nanoscale Wires with External
Layers for Sensors and Other Applications,” US Patent Application 15/563,773 filed 2 October
2017.
64. C.M. Lieber, G. Hong, T.-M. Fu and J. Huang, “Techniques and Systems for Injection and/or
Connection of Electrical Devices,” US Patent Application 15/749,617 filed 1 February 2018.
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