l********1 发帖数: 1 | 1 Awards
ACS Award in the Chemistry of Materials 2004[63]
Inorganic Nanoscience Award, ACS Division of Inorganic Chemistry 2009[64]
Fred Kavli Distinguished Lectureship in Nanoscience, Materials Research
Society 2010[65]
Wolf Prize in Chemistry 2012[66]
Nano Research Award, Tsinghua University Press/Springer 2013[67]
IEEE Nanotechnology Pioneer Award 2013[68]
Willard Gibbs Medal Award (2013)[69]
MRS Von Hippel Award 2016[70] (2016)
Remsen Award 2016 [71]
NIH Director's Pioneer Award 2017[72]
Welch Award in Chemistry 2019;[73] | l********1 发帖数: 1 | 2 Lieber's contributions to the rational growth, characterization, and
applications of a range of functional nanoscale materials and
heterostructures have provided concepts central to the bottom-up paradigm of
nanoscience. These include rational synthesis of functional nanowire
building blocks, characterization of these materials, and demonstration of
their application in areas ranging from electronics, computing, photonics,
and energy science to biology and medicine.[13]
Nanomaterials synthesis. In his early work Lieber articulated the motivation
for pursuing designed growth of nanometer-diameter wires in which
composition, size, structure and morphology could be controlled over a wide
range,[14] and outlined a general method for the first controlled synthesis
of free-standing single-crystal semiconductor nanowires,[15][16] providing
the groundwork for predictable growth of nanowires of virtually any elements
and compounds in the periodic table. He proposed and demonstrated a general
concept for the growth of nanoscale axial heterostructures[17] and the
growth of nanowire superlattices with new photonic and electronic properties
,[18] the basis of intensive efforts today in nanowire photonics and
electronics. In parallel, he proposed and demonstrated the heterojunction
concept of radial core-shell nanowire structures[19] and single-crystalline
multi-quantum well structures.[20] Lieber also demonstrated a synthetic
methodology to introduce controlled stereocenters – kinks – into nanowires
,[21] introducing the possibility of increasingly complex and functional
nanostructures for three-dimensional nanodevices.
Nanostructure characterization. Lieber developed applications of scanning
probe microscopies that could provide direct experimental measurement of the
electrical and mechanical properties of individual carbon nanotubes and
nanowires.[22][23] This work showed that semiconductor nanowires with
controlled electrical properties can be synthesized, providing
electronically tunable functional nanoscale building blocks for device
assembly. Additionally, Lieber invented chemical force microscopy to
characterize the chemical properties of materials surfaces with nanometer
resolution.[24]
Nanoelectronics and nanophotonics. Lieber has used quantum-confined core/
shell nanowire heterostructures to demonstrate ballistic transport,[25] the
superconducting proximity effect,[26] and quantum transport.[27] Other
examples of functional nanoscale electronic and optoelectronic devices
include nanoscale electrically driven lasers using single nanowires as
active nanoscale cavities,[28] carbon nanotube nanotweezers,[29] nanotube-
based ultrahigh-density electromechanical memory,[30] an all-inorganic fully
integrated nanoscale photovoltaic cell[31] and functional logic devices and
simple computational circuits using assembled semiconductor nanowires.[32]
These concepts led to the integration of nanowires on the Intel roadmap, and
their current top-down implementation of these structures.[33]
Nanostructure assembly and computing. Lieber has originated a number of
approaches for parallel and scalable of assembly of nanowire and nanotube
building blocks. The development of fluidic-directed assembly[34] and
subsequent large-scale assembly of electrically addressable parallel and
crossed nanowire arrays was cited as one of the Breakthroughs of 2001 by
Science.[35] He also developed a lithography-free approach to bridging the
macro-to-nano scale gap using modulation-doped semiconductor nanowires.[36][
37] Lieber recently introduced the assembly concept ‘nanocombing,’[38]
which can be used to align nanoscale wires in a deterministic manner
independent of material. He used this concept to create a programmable
nanowire logic tile[39] and the first stand-alone nanocomputer.[40]
Nanoelectronics for biology and medicine. Lieber demonstrated the first
direct electrical detection of proteins,[41] selective electrical sensing of
individual viruses[42] and multiplexed detection of cancer marker proteins
and tumor enzyme activity.[43] His approach uses electrical signals for high
-sensitivity, label-free detection, for use in wireless/remote medical
applications. More recently, Lieber demonstrated a general approach to
overcome the Debye screening that makes these measurements challenging in
physiological conditions,[44] overcoming the limitations of sensing with
silicon nanowire field-effect devices and opening the way to their use in
diagnostic healthcare applications. Lieber has also developed nanoelectronic
devices for cell/tissue electrophysiology, showing that electrical activity
and action potential propagation can be recorded from cultured cardiac
cells with high resolution.[45] Most recently, Lieber realized 3D nanoscale
transistors[46][47] in which the active transistor is separated from the
connections to the outside world. His nanotechnology-enabled 3D cellular
probes have shown point-like resolution in detection of single-molecules,
intracellular function and even photons.[48]
【在 l********1 的大作中提到】 : Awards : ACS Award in the Chemistry of Materials 2004[63] : Inorganic Nanoscience Award, ACS Division of Inorganic Chemistry 2009[64] : Fred Kavli Distinguished Lectureship in Nanoscience, Materials Research : Society 2010[65] : Wolf Prize in Chemistry 2012[66] : Nano Research Award, Tsinghua University Press/Springer 2013[67] : IEEE Nanotechnology Pioneer Award 2013[68] : Willard Gibbs Medal Award (2013)[69] : MRS Von Hippel Award 2016[70] (2016)
| d********f 发帖数: 43471 | 3 lieber就是个ppt王子
【在 l********1 的大作中提到】 : Awards : ACS Award in the Chemistry of Materials 2004[63] : Inorganic Nanoscience Award, ACS Division of Inorganic Chemistry 2009[64] : Fred Kavli Distinguished Lectureship in Nanoscience, Materials Research : Society 2010[65] : Wolf Prize in Chemistry 2012[66] : Nano Research Award, Tsinghua University Press/Springer 2013[67] : IEEE Nanotechnology Pioneer Award 2013[68] : Willard Gibbs Medal Award (2013)[69] : MRS Von Hippel Award 2016[70] (2016)
| l********1 发帖数: 1 | 4 看看一楼
你这是抽美帝科研界的碧莲啊。
【在 d********f 的大作中提到】 : lieber就是个ppt王子
| d********f 发帖数: 43471 | 5 本来就是事实
【在 l********1 的大作中提到】 : 看看一楼 : 你这是抽美帝科研界的碧莲啊。
| F*****d 发帖数: 2848 | |
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