Giant, Anomalous Piezoimpedance in Silicon-on-insulator

Li, H.; Lew, C. T.-K.; Johnson, Brett C.; McCallum, Jeffrey C.; Arscott, S.; Rowe, A. C. H.

doi:10.1103/physrevapplied.11.044010

Cited by 3 publications

(6 citation statements)

References 61 publications

(126 reference statements)

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“…1 and a 1 μm-thick buried oxide (BOX) layer. Devices of the type used elsewhere [25,31] are fabricated with p + -ohmic contacts (boron, 10 18 cm −3 ) shown in light blue in Fig. 1, and then cut into chips (20 × 13 mm 2 ) whose long axis is parallel to the 110 crystal direction as seen in the left panel of Fig.…”

Section: Sample Detailsmentioning

confidence: 99%

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Piezoresistance in Defect-Engineered Silicon

Thayil

Lew

et al. 2021

Phys. Rev. Applied

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The steady-state, space-charge-limited piezoresistance (PZR) of defect-engineered, silicon-on-insulator device layers containing silicon divacancy defects changes sign as a function of applied bias. Above a punch-through voltage (V t ) corresponding to the onset of a space-charge-limited hole current, the longitudinal 110 PZR π coefficient is π ≈ 65 × 10 −11 Pa −1 , similar to the value obtained in chargeneutral, p-type silicon. Below V t , the mechanical stress dependence of the Shockley-Read-Hall (SRH) recombination parameters, specifically the divacancy trap energy E T that is estimated to vary by approximately 30 μV/MPa, yields π ≈ −25 × 10 −11 Pa −1 . The combination of space-charge-limited transport and defect engineering that significantly reduces SRH recombination lifetimes makes this work directly relevant to discussions of giant or anomalous PZR at small strains in nanosilicon whose characteristic dimension is larger than a few nanometers. In this limit the reduced electrostatic dimensionality lowers V t and amplifies space-charge-limited currents and efficient SRH recombination occurs via surface defects. The results reinforce the growing evidence that in steady state, electromechanically active defects can result in anomalous, but not giant, PZR.

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Section: Sample Detailsmentioning

confidence: 99%

“…1(a). These chips are compatible with a threepoint bending apparatus and approach described elsewhere [25,31,32] that is used here to apply a time-modulated, tensile mechanical stress of approximately 20 MPa for the PZR measurements along the 110 crystal direction as indicated by the purple arrow in Fig. 1(a).…”

Section: Sample Detailsmentioning

confidence: 99%

Piezoresistance in Defect-Engineered Silicon

Thayil

Lew

et al. 2021

Phys. Rev. Applied

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“…Solid and dashed lines correspond to imaginary part of complex capacity of system of effective dipoles with approximately on order different characteristic frequencies before and after applying strain p , respectively Lack of experimental data especially concerning strain effect on low-frequency dielectric response does not allow to provide more direct confirmation of the proposed model of giant piezodielectric effect now. However, some works (Bhadra and Khastgir 2007;Bhadra et al 2008Bhadra et al , 2009Creyssels et al 2008;Li et al 2019;Milne et al 2010) indicate that giant piezodielectric effect takes place in dielectric dispersive and dynamic systems, and depends on the character and parameters of impedance or dielectric spectra.…”

Section: Change Of Parameters Of Effective Dipoles In Hopping Charge Carriers Systems Under Uniaxial Strainmentioning

confidence: 99%

Phenomenological model of giant piezodielectric effect in GaSe layered crystals

Fliunt

2020

Appl Nanosci

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Piezodielectric effect has been considered in frequency-dispersive systems dielectric response of which at low-frequencies obeys power fractional law B(j ) −(1−n) , where j is the imaginary unit, is the cyclic frequency, and n ≈ 0.8 . This type of dispersion is characteristic for solids with hopping electrical charge carriers. A phenomenological model describing the influence of uniaxial mechanical strain on the low-frequency dielectric spectra and their parameters has been proposed. The model explains that as there is increase of real and imaginary parts of complex relative dielectric constant, there is decrease of exponent n with increasing uniaxial strain. Sensitivity of parameters B and n of dielectric spectra with n ≈ 0.8 (characteristic for hopping charge carrier systems) and parameters of effective dipoles on uniaxial pressure has been estimated for high-resistivity GaSe layered crystals.

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“…Piezoresistance (PZR) in nano-silicon has received significant attention over more than a decade [1][2][3][4][5][6][7][8][9][10] partly because mechanical stress and device scaling into the nanometre range are important elements of the semiconductor roadmap [11], and partly because of multiple claims and observations of either giant or anomalous PZR that are significantly different from the usual effect observed in bulk silicon [12]. As has been noted on many occasions, unusual PZR in nano-silicon is usually correlated with equilibrium carrier depletion, and with the presence of surface-related electronic defects [2, 3, 7-10, 13, 14].…”

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confidence: 99%

“…1. Devices of the type used elsewhere [5,10] are fabricated with p ++ -ohmic contacts (Boron, 10 18 cm −3 ) shown in light blue in Fig. 1, and then cut into chips (20 mm × 13 mm) whose long axis is parallel to the 110 crystal direction as seen in the left panel of Fig.…”

mentioning

confidence: 99%

Piezoresistance in defect-engineered silicon

Li,

Thayil,

Lew

et al. 2020

Preprint

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The space-charge-limited, steady-state piezoresistance (PZR) in thin device layers of silicon-oninsulator wafers containing a nominal 10 14 cm −3 silicon divacancy defects changes sign as a function of applied bias. Above a punch-through voltage (Vt) corresponding to the onset of a Mott-Gurneylike hole current, the longitudinal 110 PZR π-coefficient is π ≈ 70 × 10 −11 Pa −1 , similar to the value obtained in charge-neutral, p-type silicon. Below Vt the mechanical stress dependence of the Shockley-Read recombination parameters, specifically the divacancy trap energy ET , yields π ≈ −25 × 10 −11 Pa −1 . This analysis suggests that anomalous (or inverse) PZR in nano-silicon occurs when currents are recombination limited due to strong reductions in carrier lifetime induced by significant densities of Shockley-Read centers, and when the reduced dimensionality lowers Vt and amplifies space-charge-limited currents.

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Giant, Anomalous Piezoimpedance in Silicon-on-insulator

Cited by 3 publications

References 61 publications

Piezoresistance in Defect-Engineered Silicon

Piezoresistance in Defect-Engineered Silicon

Phenomenological model of giant piezodielectric effect in GaSe layered crystals

Piezoresistance in defect-engineered silicon

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