%0 Journal Article %1 mart2020electrocaloric %A Mart, C %A Kämpfe, T %A Czernohorsky, M %A Eßlinger, S %A Kolodinski, S %A Wiatr, M %A Weinreich, W %A Eng, L. M. %B Applied Physics Letters %D 2020 %I American Institute of Physics %J Appl. Phys. Lett. %K a %N 4 %P 042903 %R 10.1063/5.0012746 %T The electrocaloric effect in doped hafnium oxide: Comparison of direct and indirect measurements %U https://doi.org/10.1063/5.0012746 %V 117 %X The accurate determination of electrocaloric coefficients in nanometer-thin, polycrystalline doped $HfO_2$ is challenging and has led to very different values reported in the literature. Here, we apply two different methods in order to compare and analyze reversible and irreversible or metastable contributions to the electrocaloric effect. The indirect method is based on temperature-dependent ferroelectric hysteresis characteristics. Furthermore, we apply a direct method, where electrocaloric temperature variations are observed using a specialized test structure. A comparison of both methods reveals that the indirect method dramatically overestimates the response due to thermal fatigue effects, which are caused by the migration of charged defects to the electrode interfaces. The partial transition to the antiferroelectric-like tetragonal phase is not immediately reversed to the polar Pca21 phase upon cooling. An electrocaloric coefficient of −107μCm−2K−1 is determined for a 20 nm thick Si-doped HfO2 film with the direct method, which corresponds to a ΔT of 4.4 K. This work was funded via subcontract from Globalfoundries Dresden Module One within the framework Important Project of Common European Interest (IPCEI) by the Federal Ministry for Economics and Energy and by the State of Saxony.

@article{mart2020electrocaloric, abstract = {The accurate determination of electrocaloric coefficients in nanometer-thin, polycrystalline doped $HfO_2$ is challenging and has led to very different values reported in the literature. Here, we apply two different methods in order to compare and analyze reversible and irreversible or metastable contributions to the electrocaloric effect. The indirect method is based on temperature-dependent ferroelectric hysteresis characteristics. Furthermore, we apply a direct method, where electrocaloric temperature variations are observed using a specialized test structure. A comparison of both methods reveals that the indirect method dramatically overestimates the response due to thermal fatigue effects, which are caused by the migration of charged defects to the electrode interfaces. The partial transition to the antiferroelectric-like tetragonal phase is not immediately reversed to the polar Pca21 phase upon cooling. An electrocaloric coefficient of −107μCm−2K−1 is determined for a 20 nm thick Si-doped HfO2 film with the direct method, which corresponds to a ΔT of 4.4 K. This work was funded via subcontract from Globalfoundries Dresden Module One within the framework Important Project of Common European Interest (IPCEI) by the Federal Ministry for Economics and Energy and by the State of Saxony. }, added-at = {2021-02-23T11:06:37.000+0100}, author = {Mart, C and Kämpfe, T and Czernohorsky, M and Eßlinger, S and Kolodinski, S and Wiatr, M and Weinreich, W and Eng, L. M.}, biburl = {https://www.bibsonomy.org/bibtex/2945e2d8b297a92995af9aba29c701daf/ctqmat}, booktitle = {Applied Physics Letters}, comment = {doi: 10.1063/5.0012746}, day = 28, description = {The electrocaloric effect in doped hafnium oxide: Comparison of direct and indirect measurements: Applied Physics Letters: Vol 117, No 4}, doi = {10.1063/5.0012746}, interhash = {1b6a8459f992cff5a05071ab9d10cf3b}, intrahash = {945e2d8b297a92995af9aba29c701daf}, issn = {00036951}, journal = {Appl. Phys. Lett.}, keywords = {a}, month = {07}, number = 4, pages = 042903, publisher = {American Institute of Physics}, timestamp = {2023-01-16T14:49:29.000+0100}, title = {The electrocaloric effect in doped hafnium oxide: Comparison of direct and indirect measurements}, url = {https://doi.org/10.1063/5.0012746}, volume = 117, year = 2020 }