Remarkable and Crystal‐Structure‐Dependent Piezoelectric and Piezoresistive Effects of InAs Nanowires

Li, Xing; Wei, Xianlong; Xu, Tingting; Pan, Dong; Zhao, Jianhua; Chen, Qing

doi:10.1002/adma.201500037

Cited by 60 publications

(74 citation statements)

References 47 publications

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“…For the purpose of controlling and improving semiconducting nanowire (NW) devices for various applications1234567, an extensive research effort has been invested in studying NW growth; this was typically achieved by studying the different effects of user controlled parameters: (i) materials - including type and size of NW catalyst, the growth substrates and precursors, and (ii) by altering growth-system parameters, i.e., temperature and precursor flow891011121314151617. In the following report we present a new paradigm, that of catalyst shape engineering, as a useful tool to control NW growth results; in particular, we show that by imposing a non-hemispherical shape to the catalyst-substrate interface, anisotropic cross-sectioned NWs may be grown - NWs with potentially new physical characteristics.…”

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confidence: 99%

Catalyst shape engineering for anisotropic cross-sectioned nanowire growth

Calahorra

Kelrich

Cohen

et al. 2017

Sci Rep

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The ability to engineer material properties at the nanoscale is a crucial prerequisite for nanotechnology. Hereunder, we suggest and demonstrate a novel approach to realize non-hemispherically shaped nanowire catalysts, subsequently used to grow InP nanowires with a cross section anisotropy ratio of up to 1:1.8. Gold was deposited inside high aspect ratio nanotrenches in a 5 nm thick SiN x selective area mask; inside the growth chamber, upon heating to 455 °C, the thin gold stripes agglomerated, resulting in an ellipsoidal dome (hemiellipsoid). The initial shape of the catalyst was preserved during growth to realize asymmetrically cross-sectioned nanowires. Moreover, the crystalline nature of the nanowire side facets was found to depend on the nano-trench orientation atop the substrate, resulting in hexagonal or octagonal cross-sections when the nano-trenches are aligned or misaligned with the [110] orientation atop a [111]B substrate. These results establish the role of catalyst shape as a unique tool to engineer nanowire growth, potentially allowing further control over its physical properties.For the purpose of controlling and improving semiconducting nanowire (NW) devices for various applications 1-7 , an extensive research effort has been invested in studying NW growth; this was typically achieved by studying the different effects of user controlled parameters: (i) materials -including type and size of NW catalyst, the growth substrates and precursors, and (ii) by altering growth-system parameters, i.e., temperature and precursor flow [8][9][10][11][12][13][14][15][16][17] . In the following report we present a new paradigm, that of catalyst shape engineering, as a useful tool to control NW growth results; in particular, we show that by imposing a non-hemispherical shape to the catalyst-substrate interface, anisotropic cross-sectioned NWs may be grown -NWs with potentially new physical characteristics. Furthermore, we show that the combination of a non-hemispherical catalyst with different crystalline orientations of the long axis results in non-trivial side-faceting of the grown NWs. Nanowire cross section shape and faceting is expected to influence its electrical, mechanical, optical and chemical properties [18][19][20][21][22][23][24] . In particular, Foster et al. have shown that the emission of InGaAs quantum wells embedded inside selective-area-grown anisotropically cross-sectioned GaAs NWs, exhibited linear polarization aligned with the long cross-section axis; basically, when one cross-sectional length-scale is too small to support an optical mode, the spatial degeneracy is lifted and the photoluminescence becomes linearly polarized 22 . This work is an excellent reference for catalyst free growth of anisotropic cross-sectioned NWs, and will be discussed below in further detail. Similar results have been reported by Li et al., in regards to polarisation of laser emission from top-down fabricated GaN NWs 23 . In a different case, Mankin et al. have studied the reactivity of different facets of a VLS ...

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confidence: 99%

Catalyst shape engineering for anisotropic cross-sectioned nanowire growth

Calahorra

Kelrich

Cohen

et al. 2017

Sci Rep

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“…55 However, similar measurements made on InAs nanowires have shown a similar piezo-resistance. 19 The effect was interpreted as a modulation of the Schottky barrier height. 39 However, the method presented here allows a precise measurement of the contact resistance as the difference between the two-probe resistance, measured across the central InAs nanowire segment, and the four-probe resistance.…”

Section: Discussionmentioning

confidence: 99%

“…These experiments revealed remarkable mechanical properties and modifications of the electronic properties of nanotubes 33,34 as well as of metallic 35,36 and semiconducting nanowires. 19,37,38 Those methods, however, suffer from a limited freedom of choice of the materials used to establish electrical contact with the nanostructure. As a consequence, the effect of strain on the electronic properties of the device is often dominated by Schottky contacts and by the influence that strain has on the barrier height through the piezo-electric effect.…”

Section: Introductionmentioning

confidence: 99%

An open-source platform to study uniaxial stress effects on nanoscale devices

Signorello

Schraff

Zellekens

et al. 2017

Review of Scientific Instruments

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We present an automatic measurement platform that enables the characterization of nanodevices by electrical transport and optical spectroscopy as a function of uniaxial stress. We provide insights into and detailed descriptions of the mechanical device, the substrate design and fabrication, and the instrument control software, which is provided under open-source license. The capability of the platform is demonstrated by characterizing the piezo-resistance of an InAs nanowire device using a combination of electrical transport and Raman spectroscopy. The advantages of this measurement platform are highlighted by comparison with state-of-the-art piezo-resistance measurements in InAs nanowires. We envision that the systematic application of this methodology will provide new insights into the physics of nanoscale devices and novel materials for electronics, and thus contribute to the assessment of the potential of strain as a technology booster for nanoscale electronics.2

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“…This work reveals that the piezoelectric circuit integrated by c/m-plane GaN piezotronic transistors will be modulated by any modes of external force effectively, which has a great application potential in energy collection, biomedical sciences, strain sensors, or human-machine interfaces. [35] The gauge factors for positive bias voltages are much larger than those for the corresponding negative ones, which is ascribed to the coexistence of remarkable piezoelectric and piezoresistive effects. As shown in Figure 4g, electro-mechanical measurements were performed by using two W probes to ensure symmetric NW probe contacts.…”

Section: Piezotronic Effect In Polarity-controlled Gan Nanowire (Nw)mentioning

confidence: 99%

Recent Progress on Piezotronic and Piezo‐Phototronic Effects in III‐Group Nitride Devices and Applications

Wang

2017

Adv Eng Mater

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Wurtzite-structured III-group nitrides, like GaN, InN, AlN, and their alloys, present both piezoelectric and semiconducting properties under straining owing to the polarization of ions in a crystal with non-central symmetry. The piezoelectric polarization charges are created at the interface when a strain is applied. As a result, a piezoelectric potential (piezopotential) is produced, which is used as a "gate" to tune/control the charge transport behavior across a metal/semiconductor interface or a p-n junction. This is called as piezotronic effect. A series of piezotronic devices and applications have been developed, such as piezotronic nanogenerators (NGs), piezotronic transistors, piezotronic logic devices, piezotronic electromechanical memories, piezotronic enhanced biochemical, and gas sensors and so on. With the flourished development of piezotronic effect, the piezo-phototronic effect, as the threeway coupling of piezoelectric polarization, semiconductor properties, and optical excitation, utilizes the piezopotential to modulate the energy band profile and control the carrier generation, transportation, separation, and/or recombination for improving performances of optoelectronic devices. This paper intends to provide an overview of the rapid progress in the emerging fields of piezotronics and piezo-phototronics, covering from the fundamental principles to devices and applications. This study will provide important insight into the potential applications of GaN based electronic/optoelectronic devices in sensing, active flexible/stretchable electronics/optoelectronics, energy harvesting, human-machine interfacing, biomedical diagnosis/therapy, and prosthetics. Figure 2. Piezopotential in wurtzite crystal. a) Atomic model of the wurtzite Àstructured ZnO. b) The piezopotential distributed along a ZnO NW under axial strain calculated by numerical methods. The growth direction of the NW is along the c-axis. (Reproduced with permission. [27]

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Remarkable and Crystal‐Structure‐Dependent Piezoelectric and Piezoresistive Effects of InAs Nanowires

Cited by 60 publications

References 47 publications

Catalyst shape engineering for anisotropic cross-sectioned nanowire growth

Catalyst shape engineering for anisotropic cross-sectioned nanowire growth

An open-source platform to study uniaxial stress effects on nanoscale devices

Recent Progress on Piezotronic and Piezo‐Phototronic Effects in III‐Group Nitride Devices and Applications

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