TY - JOUR
T1 - Perspectives and progress on wurtzite ferroelectrics
T2 - Synthesis, characterization, theory, and device applications
AU - Casamento, Joseph
AU - Baksa, Steven M.
AU - Behrendt, Drew
AU - Calderon, Sebastian
AU - Goodling, Devin
AU - Hayden, John
AU - He, Fan
AU - Jacques, Leonard
AU - Lee, Seung Hoon
AU - Smith, Walter
AU - Suceava, Albert
AU - Tran, Quyen
AU - Zheng, Xiaojun
AU - Zu, Rui
AU - Beechem, Thomas
AU - Dabo, Ismaila
AU - Dickey, Elizabeth C.
AU - Esteves, Giovanni
AU - Gopalan, Venkatraman
AU - Henry, Michael David
AU - Ihlefeld, Jon F.
AU - Jackson, Thomas N.
AU - Kalinin, Sergei V.
AU - Kelley, Kyle P.
AU - Liu, Yongtao
AU - Rappe, Andrew M.
AU - Redwing, Joan
AU - Trolier-McKinstry, Susan
AU - Maria, Jon Paul
N1 - Publisher Copyright:
© 2024 Author(s).
PY - 2024/2/19
Y1 - 2024/2/19
N2 - Wurtzite ferroelectrics are an emerging material class that expands the functionality and application space of wide bandgap semiconductors. Promising physical properties of binary wurtzite semiconductors include a large, reorientable spontaneous polarization, direct band gaps that span from the infrared to ultraviolet, large thermal conductivities and acoustic wave velocities, high mobility electron and hole channels, and low optical losses. The ability to reverse the polarization in ternary wurtzite semiconductors at room temperature enables memory and analog type functionality and quasi-phase matching in optical devices and boosts the ecosystem of wurtzite semiconductors, provided the appropriate combination of properties can be achieved for any given application. In this article, advances in the design, synthesis, and characterization of wurtzite ferroelectric materials and devices are discussed. Highlights include: the direct and quantitative observation of polarization reversal of ∼135 μC/cm2 charge in Al1−xBxN via electron microscopy, Al1−xBxN ferroelectric domain patterns poled down to 400 nm in width via scanning probe microscopy, and full polarization retention after over 1000 h of 200 °C baking and a 2× enhancement relative to ZnO in the nonlinear optical response of Zn1−xMgxO. The main tradeoffs, challenges, and opportunities in thin film deposition, heterostructure design and characterization, and device fabrication are overviewed.
AB - Wurtzite ferroelectrics are an emerging material class that expands the functionality and application space of wide bandgap semiconductors. Promising physical properties of binary wurtzite semiconductors include a large, reorientable spontaneous polarization, direct band gaps that span from the infrared to ultraviolet, large thermal conductivities and acoustic wave velocities, high mobility electron and hole channels, and low optical losses. The ability to reverse the polarization in ternary wurtzite semiconductors at room temperature enables memory and analog type functionality and quasi-phase matching in optical devices and boosts the ecosystem of wurtzite semiconductors, provided the appropriate combination of properties can be achieved for any given application. In this article, advances in the design, synthesis, and characterization of wurtzite ferroelectric materials and devices are discussed. Highlights include: the direct and quantitative observation of polarization reversal of ∼135 μC/cm2 charge in Al1−xBxN via electron microscopy, Al1−xBxN ferroelectric domain patterns poled down to 400 nm in width via scanning probe microscopy, and full polarization retention after over 1000 h of 200 °C baking and a 2× enhancement relative to ZnO in the nonlinear optical response of Zn1−xMgxO. The main tradeoffs, challenges, and opportunities in thin film deposition, heterostructure design and characterization, and device fabrication are overviewed.
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U2 - 10.1063/5.0185066
DO - 10.1063/5.0185066
M3 - Short survey
AN - SCOPUS:85185887515
SN - 0003-6951
VL - 124
JO - Applied Physics Letters
JF - Applied Physics Letters
IS - 8
M1 - 080501
ER -