Open AccessIncreasing bulk photovoltaic current by strain tuning
Author(s) -
Shankari Nadupalli,
J. Kreisel,
Torsten Granzow
Publication year - 2019
Publication title -
science advances
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.928
H-Index - 146
ISSN - 2375-2548
DOI - 10.1126/sciadv.aau9199
Subject(s) - photovoltaic system , anomalous photovoltaic effect , materials science , photovoltaic effect , current (fluid) , semiconductor , optoelectronics , current density , doping , stress (linguistics) , condensed matter physics , physics , electrical engineering , thermodynamics , engineering , linguistics , philosophy , quantum mechanics
Photovoltaic phenomena are widely exploited not only for primary energy generation but also in photocatalytic, photoelectrochemistry, or optoelectronic applications. In contrast to the interface-based photovoltaic effect of semiconductors, the anomalous or bulk photovoltaic effect in ferroelectrics is not bound by the Shockley-Queisser limit and, thus, can potentially reach high efficiencies. Here, we observe in the example of an Fe-doped LiNbO bulk single crystal the existence of a purely intrinsic "piezophotovoltaic" effect that leads to a linear increase in photovoltaic current density. The increase reaches 75% under a low uniaxial compressive stress of 10 MPa, corresponding to a strain of only 0.005%. The physical origin and symmetry properties of the effect are investigated, and its potential for strain-tuned efficiency increase in nonconventional photovoltaic materials is presented.
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