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Colossal piezoresistance in narrow-gap Eu5In2Sb6

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arxiv 2206.14073 v1 pith:JWE3QI4Y submitted 2022-06-28 cond-mat.str-el cond-mat.mtrl-sci

Colossal piezoresistance in narrow-gap Eu5In2Sb6

classification cond-mat.str-el cond-mat.mtrl-sci
keywords piezoresistancecolossalanisotropicdevicesinteractionslargeonlypressure
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Piezoresistance, the change of a material's electrical resistance ($R$) in response to an applied mechanical stress ($\sigma$), is the driving principle of electromechanical devices such as strain gauges, accelerometers, and cantilever force sensors. Enhanced piezoresistance has been traditionally observed in two classes of uncorrelated materials: nonmagnetic semiconductors and composite structures. We report the discovery of a remarkably large piezoresistance in Eu$_5$In$_2$Sb$_6$ single crystals, wherein anisotropic metallic clusters naturally form within a semiconducting matrix due to electronic interactions. Eu$_5$In$_2$Sb$_6$ shows a highly anisotropic piezoresistance, and uniaxial pressure along [001] of only 0.4~GPa leads to a resistivity drop of more than 99.95\% that results in a colossal piezoresistance factor of $5000\times10^{-11}$Pa$^{-1}$. Our result not only reveals the role of interactions and phase separation in the realization of colossal piezoresistance, but it also highlights a novel route to multi-functional devices with large responses to both pressure and magnetic field.

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