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12 results on '"Kuerten, Lukas"'

1. Magnetic avalanche of non-oxide conductive domain walls

Author

Ghara, Somnath, Geirhos, Korbinian, Kuerten, Lukas, Lunkenheimer, Peter, Tsurkan, Vladimir, Fiebig, Manfred, and Kézsmárki, István

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Atomically sharp domain walls (DWs) in ferroelectrics are considered as an ideal platform to realize easy-to-reconfigure nanoelectronic building blocks, created, manipulated and erased by external fields. However, conductive DWs have been exclusively observed in oxides, where DW mobility and conductivity is largely influenced by stoichiometry and defects. In contrast, we here report on conductive DWs in the non-oxide ferroelectric GaV$_4$S$_8$, where charge carriers are provided intrinsically by multivalent V$_4$ molecular clusters. We show that this new mechanism gives rise to DWs composed of nanoscale stripes with alternating electron and hole conduction, unimaginable in oxides. By exerting magnetic control on these segments we promote the mobile and effectively 2D DWs into dominating the 3D conductance, triggering abrupt conductance changes as large as eight orders of magnitude. The flexible valency, as origin of these novel hybrid DWs with giant conductivity, demonstrates that non-oxide ferroelectrics can be the source of novel phenomena beyond the realm of oxide electronics., Comment: 8 pages, 4 figures

Published
2021
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2. Local control of improper ferroelectric domains in YMnO$_3$

Author

Kuerten, Lukas, Krohns, Stephan, Schoenherr, Peggy, Holeczek, Katharina, Pomjakushina, Ekaterina, Lottermoser, Thomas, Trassin, Morgan, Meier, Dennis, and Fiebig, Manfred

Subjects
Condensed Matter - Materials Science
Abstract

Improper ferroelectrics are described by two order parameters: a primary one, driving a transition to long-range distortive, magnetic or otherwise non-electric order, and the electric polarization, which is induced by the primary order parameter as a secondary, complementary effect. Using low-temperature scanning probe microscopy, we show that improper ferroelectric domains in YMnO$_3$ can be locally switched by electric field poling. However, subsequent temperature changes restore the as-grown domain structure as determined by the primary lattice distortion. The backswitching is explained by uncompensated bound charges occuring at the newly written domain walls due to the lack of mobile screening charges at low temperature. Thus, the polarization of improper ferroelectrics is in many ways subject to the same electrostatics as in their proper counterparts, yet complemented by additional functionalities arising from the primary order parameter. Tailoring the complex interplay between primary order parameter, polarization, and electrostatics is therefore likely to result in novel functionalities specific to improper ferroelectrics.

Published
2020
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3. In-gap features in superconducting LaAlO$_3$-SrTiO$_3$ interfaces observed by tunneling spectroscopy

Author

Kuerten, Lukas, Richter, Christoph, Mohanta, Narayan, Kopp, Thilo, Kampf, Arno, Mannhart, Jochen, and Boschker, Hans

Subjects
Condensed Matter - Superconductivity
Abstract

We identified quasiparticle states at well-defined energies inside the superconducting gap of the electron system at the LaAlO$_3$-SrTiO$_3$ interface using tunneling spectroscopy. The states are found only in a number of samples and depend upon the thermal-cycling history of the samples. The states consist of a peak at zero energy and other peaks at finite energies, symmetrically placed around zero energy. These peaks disappear, together with the superconducting gap, with increasing temperature and magnetic field. We discuss the likelihood of various physical mechanisms that are known to cause in-gap states in superconductors and conclude that none of these mechanisms can easily explain the results. The conceivable scenarios are the formation of Majorana bound states, Andreev bound states, or the presence of an odd-frequency spin triplet component in the superconducting order parameter., Comment: 11 pages, 5 figures

Published
2017
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5. Local electric-field control of multiferroic spin-spiral domains in TbMnO3

Author

Swiss National Science Foundation, Japan Society for the Promotion of Science, European Research Council, Ministerio de Economía, Industria y Competitividad (España), Research Council of Norway, Norwegian University of Science and Technology, Schoenherr, Peggy, Manz, Sebastian, Kuerten, Lukas, Shapovalov, Konstantin, Iyama, Ayato, Kimura, Tsuyoshi, Fiebig, Manfred, Meier, Dennis, Swiss National Science Foundation, Japan Society for the Promotion of Science, European Research Council, Ministerio de Economía, Industria y Competitividad (España), Research Council of Norway, Norwegian University of Science and Technology, Schoenherr, Peggy, Manz, Sebastian, Kuerten, Lukas, Shapovalov, Konstantin, Iyama, Ayato, Kimura, Tsuyoshi, Fiebig, Manfred, and Meier, Dennis

Abstract

Spin-spiral multiferroics exhibit a magnetoelectric coupling effects, leading to the formation of hybrid domains with inseparably entangled ferroelectric and antiferromagnetic order parameters. Due to this strong magnetoelectric coupling, conceptually advanced ways for controlling antiferromagnetism become possible and it has been reported that electric fields and laser pulses can reversibly switch the antiferromagnetic order. This switching of antiferromagnetic spin textures is of great interest for the emergent field of antiferromagnetic spintronics. Established approaches, however, require either high voltages or intense laser fields and are currently limited to the micrometer length scale, which forfeits the technological merit. Here, we image and control hybrid multiferroic domains in the spin-spiral system TbMnO3 using low-temperature electrostatic force microscopy (EFM). First, we show that image generation in EFM happens via surface screening charges, which allows for probing the previously hidden magnetically induced ferroelectric order in TbMnO3 (PS = 6 × 10−4 C/m2). We then set the antiferromagnetic domain configuration by acting on the surface screening charges with the EFM probe tip. Our study enables detection of entangled ferroelectric and antiferromagnetic domains with high sensitivity. The spatial resolution is limited only by the physical size of the probe tip, introducing a pathway towards controlling antiferromagnetic order at the nanoscale and with low energy.

Published
2020

7. Local control of improper ferroelectric domains in YMnO3

Author

Kuerten, Lukas, primary, Krohns, Stephan, additional, Schoenherr, Peggy, additional, Holeczek, Katharina, additional, Pomjakushina, Ekaterina, additional, Lottermoser, Thomas, additional, Trassin, Morgan, additional, Meier, Dennis, additional, and Fiebig, Manfred, additional

Published
2020
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11. Investigation of LaAlO3-SrTiO3 field-effect transistors under hydrostatic pressure.

Author

Kuerten, Lukas, Zabaleta, Jone, Parks, Sarah C., Mannhart, Jochen, and Boschker, Hans

Subjects
*FIELD-effect transistors, *HYDROSTATIC pressure, *CARRIER density, *INDUCTIVE effect, *CHARGE carriers
Abstract

We have manufactured oxide field-effect transistors using the electron system at the LaAlO3-SrTiO3 interface as a drain-source channel and measured the devices under a hydrostatic pressure of up to 1.8 GPa. These studies of oxide transistors in the high-pressure regime demonstrate remarkable stability of the devices against gate leakage and resilience to mechanical strain. They show that oxide transistors can be operated in a wide range of pressures and temperatures and open the road for future studies of oxide materials and their possible applications in electronics. [ABSTRACT FROM AUTHOR]

Published
2018
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12. Local electric-field control of multiferroic spin-spiral domains in TbMnO3.

Author

Schoenherr, Peggy, Manz, Sebastian, Kuerten, Lukas, Shapovalov, Konstantin, Iyama, Ayato, Kimura, Tsuyoshi, Fiebig, Manfred, and Meier, Dennis

Subjects
MULTIFERROIC materials, ELECTRIC fields, FERROELECTRICITY, MICROMETERS, ANTIFERROMAGNETIC materials
Abstract

Spin-spiral multiferroics exhibit a magnetoelectric coupling effects, leading to the formation of hybrid domains with inseparably entangled ferroelectric and antiferromagnetic order parameters. Due to this strong magnetoelectric coupling, conceptually advanced ways for controlling antiferromagnetism become possible and it has been reported that electric fields and laser pulses can reversibly switch the antiferromagnetic order. This switching of antiferromagnetic spin textures is of great interest for the emergent field of antiferromagnetic spintronics. Established approaches, however, require either high voltages or intense laser fields and are currently limited to the micrometer length scale, which forfeits the technological merit. Here, we image and control hybrid multiferroic domains in the spin-spiral system TbMnO3 using low-temperature electrostatic force microscopy (EFM). First, we show that image generation in EFM happens via surface screening charges, which allows for probing the previously hidden magnetically induced ferroelectric order in TbMnO3 (PS = 6 × 10−4 C/m2). We then set the antiferromagnetic domain configuration by acting on the surface screening charges with the EFM probe tip. Our study enables detection of entangled ferroelectric and antiferromagnetic domains with high sensitivity. The spatial resolution is limited only by the physical size of the probe tip, introducing a pathway towards controlling antiferromagnetic order at the nanoscale and with low energy. [ABSTRACT FROM AUTHOR]

Published
2020
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