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36 results on '"Lieber, Charles M."'

1. Long term stability of nanowire nanoelectronics in physiological environments.

Author

Zhou W, Dai X, Fu TM, Xie C, Liu J, and Lieber CM

Subjects
Nanowires ultrastructure, Aluminum Oxide chemistry, Germanium chemistry, Materials Testing, Nanowires chemistry, Silicon chemistry
Abstract

Nanowire nanoelectronic devices have been exploited as highly sensitive subcellular resolution detectors for recording extracellular and intracellular signals from cells, as well as from natural and engineered/cyborg tissues, and in this capacity open many opportunities for fundamental biological research and biomedical applications. Here we demonstrate the capability to take full advantage of the attractive capabilities of nanowire nanoelectronic devices for long term physiological studies by passivating the nanowire elements with ultrathin metal oxide shells. Studies of Si and Si/aluminum oxide (Al2O3) core/shell nanowires in physiological solutions at 37 °C demonstrate long-term stability extending for at least 100 days in samples coated with 10 nm thick Al2O3 shells. In addition, investigations of nanowires configured as field-effect transistors (FETs) demonstrate that the Si/Al2O3 core/shell nanowire FETs exhibit good device performance for at least 4 months in physiological model solutions at 37 °C. The generality of this approach was also tested with in studies of Ge/Si and InAs nanowires, where Ge/Si/Al2O3 and InAs/Al2O3 core/shell materials exhibited stability for at least 100 days in physiological model solutions at 37 °C. In addition, investigations of hafnium oxide-Al2O3 nanolaminated shells indicate the potential to extend nanowire stability well beyond 1 year time scale in vivo. These studies demonstrate that straightforward core/shell nanowire nanoelectronic devices can exhibit the long term stability needed for a range of chronic in vivo studies in animals as well as powerful biomedical implants that could improve monitoring and treatment of disease.

Published
2014
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2. Tuning light absorption in core/shell silicon nanowire photovoltaic devices through morphological design.

Author

Kim SK, Day RW, Cahoon JF, Kempa TJ, Song KD, Park HG, and Lieber CM

Subjects
Computer-Aided Design, Equipment Design, Equipment Failure Analysis, Light, Particle Size, Porosity, Scattering, Radiation, Electric Power Supplies, Nanostructures chemistry, Nanostructures ultrastructure, Semiconductors, Silicon chemistry, Solar Energy
Abstract

Subwavelength diameter semiconductor nanowires can support optical resonances with anomalously large absorption cross sections, and thus tailoring these resonances to specific frequencies could enable a number of nanophotonic applications. Here, we report the design and synthesis of core/shell p-type/intrinsic/n-type (p/i/n) Si nanowires (NWs) with different sizes and cross-sectional morphologies as well as measurement and simulation of photocurrent spectra from single-NW devices fabricated from these NW building blocks. Approximately hexagonal cross-section p/i/n coaxial NWs of various diameters (170-380 nm) were controllably synthesized by changing the Au catalyst diameter, which determines core diameter, as well as shell deposition time, which determines shell thickness. Measured polarization-resolved photocurrent spectra exhibit well-defined diameter-dependent peaks. The corresponding external quantum efficiency (EQE) spectra calculated from these data show good quantitative agreement with finite-difference time-domain (FDTD) simulations and allow assignment of the observed peaks to Fabry-Perot, whispering-gallery, and complex high-order resonant absorption modes. This comparison revealed a systematic red-shift of equivalent modes as a function of increasing NW diameter and a progressive increase in the number of resonances. In addition, tuning shell synthetic conditions to enable enhanced growth on select facets yielded NWs with approximately rectangular cross sections; analysis of transmission electron microscopy and scanning electron microscopy images demonstrate that growth of the n-type shell at 860 °C in the presence of phosphine leads to enhanced relative Si growth rates on the four {113} facets. Notably, polarization-resolved photocurrent spectra demonstrate that at longer wavelengths the rectangular cross-section NWs have narrow and significantly larger amplitude peaks with respect to similar size hexagonal NWs. A rectangular NW with a diameter of 260 nm yields a dominant mode centered at 570 nm with near-unity EQE in the transverse-electric polarized spectrum. Quantitative comparisons with FDTD simulations demonstrate that these new peaks arise from cavity modes with high symmetry that conform to the cross-sectional morphology of the rectangular NW, resulting in low optical loss of the mode. The ability to modulate absorption with changes in nanoscale morphology by controlled synthesis represents a promising route for developing new photovoltaic and optoelectronic devices.

Published
2012
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3. Kinked p-n junction nanowire probes for high spatial resolution sensing and intracellular recording.

Author

Jiang Z, Qing Q, Xie P, Gao R, and Lieber CM

Subjects
Animals, Cells, Cultured, Equipment Design, Equipment Failure Analysis, Nanotubes ultrastructure, Action Potentials physiology, Electrodes, Nanotechnology instrumentation, Nanotubes chemistry, Neurons physiology, Semiconductors, Silicon chemistry
Abstract

Semiconductor nanowires and other semiconducting nanoscale materials configured as field-effect transistors have been studied extensively as biological/chemical (bio/chem) sensors. These nanomaterials have demonstrated high-sensitivity from one- and two-dimensional sensors, although the realization of the ultimate pointlike detector has not been achieved. In this regard, nanoscale p-n diodes are attractive since the device element is naturally localized near the junction, and while nanowire p-n diodes have been widely studied as photovoltaic devices, their applications as bio/chem sensors have not been explored. Here we demonstrate that p-n diode devices can serve as a new and powerful family of highly localized biosensor probes. Designed nanoscale axial p-n junctions were synthetically introduced at the joints of kinked silicon nanowires. Scanning electron microscopy images showed that the kinked nanowire structures were achieved, and electrical transport measurements exhibited rectifying behavior with well-defined turn-on in forward bias as expected for a p-n diode. In addition, scanning gate microscopy demonstrated that the most sensitive region of these nanowires was localized near the kinked region at the p-n junction. High spatial resolution sensing using these p-n diode probes was carried out in aqueous solution using fluorescent charged polystyrene nanobeads. Multiplexed electrical measurements show well-defined single-nanoparticle detection, and experiments with simultaneous confocal imaging correlate directly the motion of the nanobeads with the electrical signals recorded from the p-n devices. In addition, kinked p-n junction nanowires configured as three-dimensional probes demonstrate the capability of intracellular recording of action potentials from electrogenic cells. These p-n junction kinked nanowire devices, which represent a new way of constructing nanoscale probes with highly localized sensing regions, provide substantial opportunity in areas ranging from bio/chem sensing and nanoscale photon detection to three-dimensional recording from within living cells and tissue., (© 2012 American Chemical Society)

Published
2012
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4. Frequency domain detection of biomolecules using silicon nanowire biosensors.

Author

Zheng G, Gao XP, and Lieber CM

Subjects
Antigen-Antibody Reactions, Biosensing Techniques, Nanowires, Silicon
Abstract

We demonstrate a new protein detection methodology based upon frequency domain electrical measurement using silicon nanowire field-effect transistor (SiNW FET) biosensors. The power spectral density of voltage from a current-biased SiNW FET shows 1/f-dependence in frequency domain for measurements of antibody functionalized SiNW devices in buffer solution or in the presence of protein not specific to the antibody receptor. In the presence of protein (antigen) recognized specifically by the antibody-functionalized SiNW FET, the frequency spectrum exhibits a Lorentzian shape with a characteristic frequency of several kilohertz. Frequency and conventional time domain measurements carried out with the same device as a function of antigen concentration show more than 10-fold increase in detection sensitivity in the frequency domain data. These concentration-dependent results together with studies of antibody receptor density effect further address possible origins of the Lorentzian frequency spectrum. Our results show that frequency domain measurements can be used as a complementary approach to conventional time domain measurements for ultrasensitive electrical detection of proteins and other biomolecules using nanoscale FETs.

Published
2010
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5. Diameter-dependent dopant location in silicon and germanium nanowires.

Author

Xie P, Hu Y, Fang Y, Huang J, and Lieber CM

Subjects
Materials Testing, Germanium chemistry, Nanotechnology methods, Nanowires chemistry, Silicon chemistry, Surface Properties
Abstract

We report studies defining the diameter-dependent location of electrically active dopants in silicon (Si) and germanium (Ge) nanowires (NWs) prepared by nanocluster catalyzed vapor-liquid-solid (VLS) growth without measurable competing homogeneous decomposition and surface overcoating. The location of active dopants was assessed from electrical transport measurements before and after removal of controlled thicknesses of material from NW surfaces by low-temperature chemical oxidation and etching. These measurements show a well-defined transition from bulk-like to surface doping as the diameter is decreased <22-25 nm for n- and p-type Si NWs, although the surface dopant concentration is also enriched in the larger diameter Si NWs. Similar diameter-dependent results were also observed for n-type Ge NWs, suggesting that surface dopant segregation may be general for small diameter NWs synthesized by the VLS approach. Natural surface doping of small diameter semiconductor NWs is distinct from many top-down fabricated NWs, explains enhanced transport properties of these NWs and could yield robust properties in ultrasmall devices often dominated by random dopant fluctuations.

Published
2009
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6. Controlled synthesis of millimeter-long silicon nanowires with uniform electronic properties.

Author

Park WI, Zheng G, Jiang X, Tian B, and Lieber CM

Subjects
Microscopy, Electron, Scanning, Nanowires, Silicon chemistry
Abstract

We report the nanocluster-catalyzed growth of ultralong and highly uniform single-crystalline silicon nanowires (SiNWs) with millimeter-scale lengths and aspect ratios up to approximately 100,000. The average SiNW growth rate using disilane (Si 2H 6) at 400 degrees C was 31 microm/min, while the growth rate determined for silane (SiH 4) reactant under similar growth conditions was 130 times lower. Transmission electron microscopy studies of millimeter-long SiNWs with diameters of 20-80 nm show that the nanowires grow preferentially along the 110 direction independent of diameter. In addition, ultralong SiNWs were used as building blocks to fabricate one-dimensional arrays of field-effect transistors (FETs) consisting of approximately 100 independent devices per nanowire. Significantly, electrical transport measurements demonstrated that the millimeter-long SiNWs had uniform electrical properties along the entire length of wires, and each device can behave as a reliable FET with an on-state current, threshold voltage, and transconductance values (average +/-1 standard deviation) of 1.8 +/- 0.3 microA, 6.0 +/- 1.1 V, 210 +/- 60 nS, respectively. Electronically uniform millimeter-long SiNWs were also functionalized with monoclonal antibody receptors and used to demonstrate multiplexed detection of cancer marker proteins with a single nanowire. The synthesis of structurally and electronically uniform ultralong SiNWs may open up new opportunities for integrated nanoelectronics and could serve as unique building blocks linking integrated structures from the nanometer through millimeter length scales.

Published
2008
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7. Sub-100 nanometer channel length Ge/Si nanowire transistors with potential for 2 THz switching speed.

Author

Hu Y, Xiang J, Liang G, Yan H, and Lieber CM

Subjects
Microscopy, Electron, Scanning, Nanowires ultrastructure, Time Factors, Transistors, Electronic, Germanium chemistry, Nanowires chemistry, Silicon chemistry
Abstract

Ge/Si core/shell nanowires (NWs) are attractive and flexible building blocks for nanoelectronics ranging from field-effect transistors (FETs) to low-temperature quantum devices. Here we report the first studies of the size-dependent performance limits of Ge/Si NWFETs in the sub-100 nm channel length regime. Metallic nanoscale electrical contacts were made and used to define sub-100 nm Ge/Si channels by controlled solid-state conversion of Ge/Si NWs to NiSixGe y alloys. Electrical transport measurements and modeling studies demonstrate that the nanoscale metallic contacts overcome deleterious short-channel effects present in lithographically defined sub-100 nm channels. Data acquired on 70 and 40 nm channel length Ge/Si NWFETs with a drain-source bias of 0.5 V yield transconductance values of 78 and 91 microS, respectively, and maximum on-currents of 121 and 152 microA. The scaled transconductance and on-current values for a gate and bias voltage window of 0.5 V were 6.2 mS/microm and 2.1 mA/microm, respectively, for the 40 nm device and exceed the best reported values for planar Si and NW p-type FETs. In addition, analysis of the intrinsic switching delay shows that terahertz intrinsic operation speed is possible when channel length is reduced to 70 nm and that an intrinsic delay of 0.5 ps is achievable in our 40 nm device. Comparison of the experimental data with simulations based on a semiclassical, ballistic transport model suggests that these sub-100 nm Ge/Si NWFETs with integrated high-kappa gate dielectric operate near the ballistic limit.

Published
2008
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8. Si/a-Si core/shell nanowires as nonvolatile crossbar switches.

Author

Dong Y, Yu G, McAlpine MC, Lu W, and Lieber CM

Subjects
Crystallization methods, Equipment Design, Equipment Failure Analysis, Materials Testing, Nanotechnology methods, Nanotubes ultrastructure, Particle Size, Electric Wiring, Electronics instrumentation, Microelectrodes, Nanotechnology instrumentation, Nanotubes chemistry, Signal Processing, Computer-Assisted instrumentation, Silicon chemistry
Abstract

Radial core/shell nanowires (NWs) represent an important class of nanoscale building blocks with substantial potential for exploring fundamental electronic properties and realizing novel device applications at the nanoscale. Here, we report the synthesis of crystalline silicon/amorphous silicon (Si/a-Si) core/shell NWs and studies of crossed Si/a-Si NW metal NW (Si/a-Si x M) devices and arrays. Room-temperature electrical measurements on single Si/a-Si x Ag NW devices exhibit bistable switching between high (off) and low (on) resistance states with well-defined switching threshold voltages, on/off ratios greater than 10(4), and current rectification in the on state. Temperature-dependent switching experiments suggest that rectification can be attributed to barriers to electric field-driven metal diffusion. Systematic studies of Si/a-Si x Ag NW devices show that (i) the bit size can be at least as small as 20 nm x 20 nm, (ii) the writing time is <100 ns, (iii) the retention time is >2 weeks, and (iv) devices can be switched >10(4) times without degradation in performance. In addition, studies of dense one-dimensional and two-dimensional Si/a-Si x Ag NW devices arrays fabricated on crystalline and plastic substrates show that elements within the arrays can be independently switched and read, and moreover that bends with radii of curvature as small as 0.3 cm cause little change in device characteristics. The Si/a-Si x Ag NW devices represent a highly scalable and promising nanodevice element for assembly and fabrication of dense nonvolatile memory and programmable nanoprocessors.

Published
2008
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9. A Ge/Si heterostructure nanowire-based double quantum dot with integrated charge sensor.

Author

Hu Y, Churchill HO, Reilly DJ, Xiang J, Lieber CM, and Marcus CM

Subjects
Electric Wiring instrumentation, Electric Wiring methods, Equipment Design, Nanotechnology trends, Nanotubes ultrastructure, Quantum Theory, Static Electricity, Systems Integration, Germanium chemistry, Nanotechnology instrumentation, Nanotubes chemistry, Quantum Dots, Semiconductors, Silicon chemistry, Transducers
Abstract

One proposal for a solid-state-based quantum bit (qubit) is to control coupled electron spins on adjacent semiconductor quantum dots. Most experiments have focused on quantum dots made from III-V semiconductors; however, the coherence of electron spins in these materials is limited by hyperfine interactions with nuclear spins. Ge/Si core/shell nanowires seem ideally suited to overcome this limitation, because the most abundant nuclei in Ge and Si have spin zero and the nanowires can be chemically synthesized defect-free with tunable properties. Here, we present a double quantum dot based on Ge/Si nanowires in which we can completely control the coupling between the dots and to the leads. We also demonstrate that charge on the double dot can be detected by coupling it capacitively to an adjacent nanowire quantum dot. The double quantum dot and integrated charge sensor serve as an essential building block to form a solid-state qubit free of nuclear spin.

Published
2007
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10. Ge/Si nanowire mesoscopic Josephson junctions.

Author

Xiang J, Vidan A, Tinkham M, Westervelt RM, and Lieber CM

Subjects
Electric Conductivity, Equipment Design, Electric Wiring instrumentation, Germanium chemistry, Nanotechnology instrumentation, Nanotubes chemistry, Nanotubes ultrastructure, Semiconductors, Silicon chemistry
Abstract

The controlled growth of nanowires (NWs) with dimensions comparable to the Fermi wavelengths of the charge carriers allows fundamental investigations of quantum confinement phenomena. Here, we present studies of proximity-induced superconductivity in undoped Ge/Si core/shell NW heterostructures contacted by superconducting leads. By using a top gate electrode to modulate the carrier density in the NW, the critical supercurrent can be tuned from zero to greater than 100 nA. Furthermore, discrete sub-bands form in the NW due to confinement in the radial direction, which results in stepwise increases in the critical current as a function of gate voltage. Transport measurements on these superconductor-NW-superconductor devices reveal high-order (n = 25) resonant multiple Andreev reflections, indicating that the NW channel is smooth and the charge transport is highly coherent. The ability to create and control coherent superconducting ordered states in semiconductor-superconductor hybrid nanostructures allows for new opportunities in the study of fundamental low-dimensional superconductivity.

Published
2006
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11. Ge/Si nanowire heterostructures as high-performance field-effect transistors.

Author

Xiang J, Lu W, Hu Y, Wu Y, Yan H, and Lieber CM

Subjects
Nanotubes, Carbon chemistry, Germanium chemistry, Nanostructures chemistry, Silicon chemistry, Transistors, Electronic
Abstract

Semiconducting carbon nanotubes and nanowires are potential alternatives to planar metal-oxide-semiconductor field-effect transistors (MOSFETs) owing, for example, to their unique electronic structure and reduced carrier scattering caused by one-dimensional quantum confinement effects. Studies have demonstrated long carrier mean free paths at room temperature in both carbon nanotubes and Ge/Si core/shell nanowires. In the case of carbon nanotube FETs, devices have been fabricated that work close to the ballistic limit. Applications of high-performance carbon nanotube FETs have been hindered, however, by difficulties in producing uniform semiconducting nanotubes, a factor not limiting nanowires, which have been prepared with reproducible electronic properties in high yield as required for large-scale integrated systems. Yet whether nanowire field-effect transistors (NWFETs) can indeed outperform their planar counterparts is still unclear. Here we report studies on Ge/Si core/shell nanowire heterostructures configured as FETs using high-kappa dielectrics in a top-gate geometry. The clean one-dimensional hole-gas in the Ge/Si nanowire heterostructures and enhanced gate coupling with high-kappa dielectrics give high-performance FETs values of the scaled transconductance (3.3 mS microm(-1)) and on-current (2.1 mA microm(-1)) that are three to four times greater than state-of-the-art MOSFETs and are the highest obtained on NWFETs. Furthermore, comparison of the intrinsic switching delay, tau = CV/I, which represents a key metric for device applications, shows that the performance of Ge/Si NWFETs is comparable to similar length carbon nanotube FETs and substantially exceeds the length-dependent scaling of planar silicon MOSFETs.

Published
2006
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12. Fabrication of silicon nanowire devices for ultrasensitive, label-free, real-time detection of biological and chemical species.

Author

Patolsky F, Zheng G, and Lieber CM

Subjects
Nucleic Acids analysis, Proteins analysis, Viruses isolation & purification, Microarray Analysis, Nanowires, Silicon chemistry
Abstract

Detection and quantification of biological and chemical species are central to many areas of healthcare and the life sciences, ranging from diagnosing disease to discovery and screening of new drug molecules. Semiconductor nanowires configured as electronic devices have emerged as a general platform for ultra-sensitive direct electrical detection of biological and chemical species. Here we describe a detailed protocol for realizing nanowire electronic sensors. First, the growth of uniform, single crystal silicon nanowires, and subsequent isolation of the nanowires as stable suspensions are outlined. Second, fabrication of addressable nanowire device arrays is described. Third, covalent modification of the nanowire device surfaces with receptors is described. Fourth, an example modification and measurements of the electrical response from devices are detailed. The silicon nanowire (SiNW) devices have demonstrated applications for label-free, ultrasensitive and highly-selective real-time detection of a wide range of biological and chemical species, including proteins, nucleic acids, small molecules and viruses.

Published
2006
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13. Coherent single charge transport in molecular-scale silicon nanowires.

Author

Zhong Z, Fang Y, Lu W, and Lieber CM

Subjects
Nanostructures chemistry, Oscillometry, Temperature, Time Factors, Nanotechnology methods, Nanotubes chemistry, Silicon chemistry
Abstract

We report low-temperature electrical transport studies of chemically synthesized, molecular-scale silicon nanowires. Individual nanowires exhibit Coulomb blockade oscillations characteristic of charge addition to a single nanostructure on length scales up to at least 400 nm. Studies also demonstrate coherent charge transport through discrete single particle quantum levels extending across whole devices, and show that the ground-state spin configuration is consistent with the constant interaction model. In addition, depletion of nanowires suggests that phase coherent single-dot characteristics are accessible in the few-charge regime. These results differ from those for nanofabricated planar silicon devices, which show localization on much shorter length scales, and thus suggest potential for molecular-scale silicon nanowires as building blocks for quantum and conventional electronics.

Published
2005
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14. Imaging and analysis of nanowires.

Author

Bell DC, Wu Y, Barrelet CJ, Gradecak S, Xiang J, Timko BP, and Lieber CM

Subjects
Electron Probe Microanalysis methods, Microscopy, Electron, Scanning Transmission methods, Computer Simulation, Metals, Heavy chemistry, Nanostructures chemistry, Silicon chemistry
Abstract

We used vapor-liquid-solid (VLS) methods to synthesize discrete single-element semiconductor nanowires and multicomposition nanowire heterostructures, and then characterized their structure and composition using high-resolution electron microscopy (HRTEM) and analytical electron microscopy techniques. Imaging nanowires requires the modification of the established HRTEM imaging procedures for bulk material to take into consideration the effects of finite nanowire width and thickness. We show that high-resolution atomic structure images of nanowires less than 6 nm in thickness have lattice "streaking" due to the finite crystal lattice in two dimensions of the nanowire structure. Diffraction pattern analysis of nanowires must also consider the effects of a finite structure producing a large reciprocal space function, and we demonstrate that the classically forbidden 1/3 [422] reflections are present in the [111] zone axis orientation of silicon nanowires due to the finite thickness and lattice plane edge effects that allow incomplete diffracted beam cancellation. If the operating conditions are not carefully considered, we found that HRTEM image delocalization becomes apparent when employing a field emission transmission electron microscope (TEM) to image nanowires and such effects have been shown to produce images of the silicon lattice structure outside of the nanowire itself. We show that pseudo low-dose imaging methods are effective in reducing nanowire structure degradation caused by electron beam irradiation. We also show that scanning TEM (STEM) with energy dispersive X-ray microanalysis (EDS) is critical in the examination of multicomponent nanowire heterostructures., (2004 Wiley-Liss, Inc.)

Published
2004
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30. Three-dimensional macroporous nanoelectronic networks as minimally invasive brain probes.

Author

Xie, Chong, Liu, Jia, Fu, Tian-Ming, Dai, Xiaochuan, Zhou, Wei, and Lieber, Charles M.

Subjects
ELECTRONIC probes, NANOELECTRONICS, SILICON, NEUROSCIENCES, SOMATOSENSORY cortex
Abstract

Direct electrical recording and stimulation of neural activity using micro-fabricated silicon and metal micro-wire probes have contributed extensively to basic neuroscience and therapeutic applications; however, the dimensional and mechanical mismatch of these probes with the brain tissue limits their stability in chronic implants and decreases the neuron-device contact. Here, we demonstrate the realization of a three-dimensional macroporous nanoelectronic brain probe that combines ultra-flexibility and subcellular feature sizes to overcome these limitations. Built-in strains controlling the local geometry of the macroporous devices are designed to optimize the neuron/probe interface and to promote integration with the brain tissue while introducing minimal mechanical perturbation. The ultra-flexible probes were implanted frozen into rodent brains and used to record multiplexed local field potentials and single-unit action potentials from the somatosensory cortex. Significantly, histology analysis revealed filling-in of neural tissue through the macroporous network and attractive neuron-probe interactions, consistent with long-term biocompatibility of the device. [ABSTRACT FROM AUTHOR]

Published
2015
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31. Hole spin relaxation in Ge-Si core-shell nanowire qubits.

Author

Hu, Yongjie, Kuemmeth, Ferdinand, Lieber, Charles M., and Marcus, Charles M.

Subjects
NANOWIRES, RELAXATION (Nuclear physics), GALLIUM arsenide, GERMANIUM, SILICON
Abstract

Controlling decoherence is the biggest challenge in efforts to develop quantum information hardware. Single electron spins in gallium arsenide are a leading candidate among implementations of solid-state quantum bits, but their strong coupling to nuclear spins produces high decoherence rates. Group IV semiconductors, on the other hand, have relatively low nuclear spin densities, making them an attractive platform for spin quantum bits. However, device fabrication remains a challenge, particularly with respect to the control of materials and interfaces. Here, we demonstrate state preparation, pulsed gate control and charge-sensing spin readout of hole spins confined in a Ge-Si core-shell nanowire. With fast gating, we measure T1 spin relaxation times of up to 0.6 ms in coupled quantum dots at zero magnetic field. Relaxation time increases as the magnetic field is reduced, which is consistent with a spin-orbit mechanism that is usually masked by hyperfine contributions. [ABSTRACT FROM AUTHOR]

Published
2012
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32. Nanowire transistor arrays for mapping neural circuits in acute brain slices.

Author

Quan Qing, Pal, Sumon K., Tian, Bozhi, Xiaojie Duan, Timko, Brian P., Cohen-Karni, Tzahi, Murthy, Venkatesh N., and Lieber, Charles M.

Subjects
PATCH-clamp techniques (Electrophysiology), SILICON, FIELD-effect transistors, NEURONS, TISSUE slices
Abstract

Revealing the functional connectivity in natural neuronal networks is central to understanding circuits in the brain. Here, we show that silicon nanowire field-effect transistor (Si NWFET) arrays fabricated on transparent substrates can be reliably interfaced to acute brain slices. NWFET arrays were readily designed to record across a wide range of length scales, while the transparent device chips enabled imaging of individual cell bodies and identification of areas of healthy neurons at both upper and lower tissue surfaces. Simultaneous NWFET and patch clamp studies enabled unambiguous identification of action potential signals, with additional features detected at earlier times by the nanodevices. NWFET recording at different positions in the absence and presence of synaptic and ion-channel blockers enabled assignment of these features to presynaptic firing and postsynaptic depolarization from regions either close to somata or abundant in dendritic projections. In all cases, the NWFET signal amplitudes were from 0.3-3 mV. In contrast to conventional multielectrode array measurements, the small active surface of the NWFET devices, ∼0.06 μm², provides highly localized multiplexed measurements of neuronal activities with demonstrated sub-millisecond temporal resolution and, significantly, better than 30 μm spatial resolution. In addition, multiplexed mapping with 2D NWFET arrays revealed spatially heterogeneous functional connectivity in the olfactory cortex with a resolution surpassing substantially previous electrical recording techniques. Our demonstration of simultaneous high temporal and spatial resolution recording, as well as mapping of functional connectivity, suggest that NWFETs can become a powerful platform for studying neural circuits in the brain. [ABSTRACT FROM AUTHOR]

Published
2010
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33. Coaxial silicon nanowires as solar cells and nanoelectronic power sources.

Author

Tian, Bozhi, Zheng, Xiaolin, Kempa, Thomas J., Fang, Ying, Yu, Nanfang, Yu, Guihua, Huang, Jinlin, and Lieber, Charles M.

Subjects
SOLAR cells, MICROELECTRONICS, NANOWIRES, NANOTECHNOLOGY, PHOTOVOLTAIC power systems, POWER electronics, SILICON, ELECTRIC conductivity, SCIENTIFIC method
Abstract

Solar cells are attractive candidates for clean and renewable power; with miniaturization, they might also serve as integrated power sources for nanoelectronic systems. The use of nanostructures or nanostructured materials represents a general approach to reduce both cost and size and to improve efficiency in photovoltaics. Nanoparticles, nanorods and nanowires have been used to improve charge collection efficiency in polymer-blend and dye-sensitized solar cells, to demonstrate carrier multiplication, and to enable low-temperature processing of photovoltaic devices. Moreover, recent theoretical studies have indicated that coaxial nanowire structures could improve carrier collection and overall efficiency with respect to single-crystal bulk semiconductors of the same materials. However, solar cells based on hybrid nanoarchitectures suffer from relatively low efficiencies and poor stabilities. In addition, previous studies have not yet addressed their use as photovoltaic power elements in nanoelectronics. Here we report the realization of p-type/intrinsic/n-type (p-i-n) coaxial silicon nanowire solar cells. Under one solar equivalent (1-sun) illumination, the p-i-n silicon nanowire elements yield a maximum power output of up to 200 pW per nanowire device and an apparent energy conversion efficiency of up to 3.4 per cent, with stable and improved efficiencies achievable at high-flux illuminations. Furthermore, we show that individual and interconnected silicon nanowire photovoltaic elements can serve as robust power sources to drive functional nanoelectronic sensors and logic gates. These coaxial silicon nanowire photovoltaic elements provide a new nanoscale test bed for studies of photoinduced energy/charge transport and artificial photosynthesis, and might find general usage as elements for powering ultralow-power electronics and diverse nanosystems. [ABSTRACT FROM AUTHOR]

Published
2007
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34. A Ge/Si heterostructure nanowire-based double quantum dot with integrated charge sensor.

Author

Yongjie Hu, Churchill, Hugh O. H., Reilly, David J., Jie Xiang, Lieber, Charles M., and Marcus, Charles M.

Subjects
QUANTUM dots, QUANTUM chemistry, ELECTRONS, GERMANIUM, NANOSILICON, SILICON
Abstract

One proposal for a solid-state-based quantum bit (qubit) is to control coupled electron spins on adjacent semiconductor quantum dots. Most experiments have focused on quantum dots made from III–V semiconductors; however, the coherence of electron spins in these materials is limited by hyperfine interactions with nuclear spins. Ge/Si core/shell nanowires seem ideally suited to overcome this limitation, because the most abundant nuclei in Ge and Si have spin zero and the nanowires can be chemically synthesized defect-free with tunable properties. Here, we present a double quantum dot based on Ge/Si nanowires in which we can completely control the coupling between the dots and to the leads. We also demonstrate that charge on the double dot can be detected by coupling it capacitively to an adjacent nanowire quantum dot. The double quantum dot and integrated charge sensor serve as an essential building block to form a solid-state qubit free of nuclear spin. [ABSTRACT FROM AUTHOR]

Published
2007
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35. Diameter-controlled synthesis of single-crystal silicon nanowires.

Author

Cui, Yi, Lauhon, Lincoln J., Gudiksen, Mark S., Wang, Jianfang, and Lieber, Charles M.

Subjects
NANOWIRES, SILICON, BIOSYNTHESIS
Abstract

Monodisperse silicon nanowires were synthesized by exploiting well-defined gold nanoclusters as catalysts for one-dimensional growth via a vapor-liquid-solid mechanism. Transmission electron microscopy studies of the materials grown from 5, 10, 20, and 30 nm nanocluster catalysts showed that the nanowires had mean diameters of 6, 12, 20, and 31 nm, respectively, and were thus well defined by the nanocluster sizes. High-resolution transmission electron microscopy demonstrated that the nanowires have single-crystal silicon cores sheathed with 1-3 nm of amorphous oxide and that the cores remain highly crystalline for diameters as small as 2 nm. [ABSTRACT FROM AUTHOR]

Published
2001
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36. Outside Looking In: NanotubeTransistor IntracellularSensors.

Author

Gao, Ruixuan, Strehle, Steffen, Tian, Bozhi, Cohen-Karni, Tzahi, Xie, Ping, Duan, Xiaojie, Qing, Quan, and Lieber, Charles M.

Subjects
*FIELD-effect transistors, *NANOTUBES, *DETECTORS, *MICROFABRICATION, *SILICON, *GATE array circuits, *AQUEOUS solutions
Abstract

Nanowire-based field-effect transistors, including deviceswithplanar and three-dimensional configurations, are being actively exploredas detectors for extra- and intracellular recording due to their smallsize and high sensitivities. Here we report the synthesis, fabrication,and characterization of a new needle-shaped nanoprobe based on anactive silicon nanotube transistor, ANTT, that enables high-resolutionintracellular recording. In the ANTT probe, the source/drain contactsto the silicon nanotube are fabricated on one end, passivated fromexternal solution, and then time-dependent changes in potential canbe recorded from the opposite nanotube end via the solution fillingthe tube. Measurements of conductance versus water-gate potentialin aqueous solution show that the ANTT probe is selectively gatedby potential changes within the nanotube, thus demonstrating the basicoperating principle of the ANTT device. Studies interfacing the ANTTprobe with spontaneously beating cardiomyocytes yielded stable intracellularaction potentials similar to those reported by other electrophysiologicaltechniques. In addition, the straightforward fabrication of ANTT deviceswas exploited to prepare multiple ANTT structures at the end of singleprobes, which enabled multiplexed recording of intracellular actionpotentials from single cells and multiplexed arrays of single ANTTdevice probes. These studies open up unique opportunities for multisiterecordings from individual cells through cellular networks. [ABSTRACT FROM AUTHOR]

Published
2012
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