Atomic-scale observations of electrical and mechanical manipulation of topological polar flux closure

Li, Xiaomei; Tan, Congbing; Liu, Chang; Gao, Peng; Sun, Yuanwei; Chen, Pan; Li, Mingqiang; Liao, Lei; Zhu, Ruixue; Wang, Jinbin; Zhao, Yanchong; Wang, Lifen; Xu, Zhi; Liu, Kaihui; Zhong, Xiangli; Wang, Jie; Bai, Xuedong

doi:10.1073/pnas.2007248117

Cited by 57 publications

(38 citation statements)

References 44 publications

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“…Aberration corrected scanning transmission electron microscopy (STEM) allows the multiferroic research community to investigate domain wall (DW) topologies at the sub-atomic scale. [24][25][26][27][28][29][30][31] Using STEM we can quantify the atomic displacements and thus polarisation changes at and within topologies. Recently, Campanini, M., et al 32 Additionally, we have found that polar vortex topologies were present in regions where out-ofphase boundaries (OPB) defects are spaced between 5 to 8 perovskite cells apart.…”

Section: Introductionmentioning

confidence: 99%

Charged Domain Wall and Polar Vortex Topologies in a Room Temperature Magnetoelectric Multiferroic Thin Film

Moore

O’Connell

Griffin

et al. 2021

Preprint

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Multiferroic topologies are an emerging solution for future low-power magnetic nanoelectronics due to their combined tuneable functionality and mobility. Here, we show that in addition to being magnetoelectric multiferroic at room temperature, thin film Aurivillius phase Bi6TixFeyMnzO18 is an ideal material platform for both domain wall and vortex topology based nanoelectronic devices. Utilising atomic resolution electron microscopy, we reveal the presence and structure of 180˚ type charged head-to-head and tail-to-tail domain walls passing throughout the thin film. Theoretical calculations confirm the sub-unit cell cation site preference and charged domain wall energetics for Bi6TixFeyMnzO18. Finally, we show that polar vortex type topologies also form at out-of-phase boundaries of stacking faults when internal strain and electrostatic energy gradients are altered. This study could pave the way for controlled polar vortex topology formation via strain engineering in other multiferroic thin films. Moreover, these results confirm the sub-unit-cell topological features play an important role in controlling the charge and spin state of Aurivillius phase films and other multiferroic heterostructures.

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Section: Introductionmentioning

confidence: 99%

Charged Domain Wall and Polar Vortex Topologies in a Room Temperature Magnetoelectric Multiferroic Thin Film

Moore

O’Connell

Griffin

et al. 2021

Preprint

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“…[ 49 , 62 , 63 , 64 , 65 , 66 , 67 ] In addition, the interaction of lattice, orbitals, charges, and spins at the heterogeneous interface produces peculiar physical properties, such as “improper ferroelectricity” in short‐period superlattices, ordered vortex arrays in mid‐period superlattices, and flux‐closed domain structures in large‐period superlattices. [ 68 , 69 , 70 , 71 , 72 , 73 ] These phenomena are important for researchers to understand the involved physical phenomena. The influence of this novel properties on the energy storage characteristics of multilayer dielectric needs to be explored.…”

Section: Basic Theory Of Multilayer Structure Dielectricsmentioning

confidence: 99%

Recent Advances in Multilayer‐Structure Dielectrics for Energy Storage Application

et al. 2021

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An electrostatic capacitor has been widely used in many fields (such as high pulsed power technology, new energy vehicles, etc.) due to its ultrahigh discharge power density. Remarkable progress has been made over the past 10 years by doping ferroelectric ceramics into polymers because the dielectric constant is positively correlated with the energy storage density. However, this method often leads to an increase in dielectric loss and a decrease in energy storage efficiency. Therefore, the way of using a multilayer structure to improve the energy storage density of the dielectric has attracted the attention of researchers. Although research on energy storage properties using multilayer dielectric is just beginning, it shows the excellent effect and huge potential. In this review, the main physical mechanisms of polarization, breakdown and energy storage in multilayer structure dielectric are introduced, the theoretical simulation and experimental results are systematically summarized, and the preparation methods and design ideas of multilayer structure dielectrics are mainly described. This article covers not only an overview of the state-of-the-art advances of multilayer structure energy storage dielectric but also the prospects that may open another window to tune the electrical performance of the electrostatic capacitor via designing a multilayer structure.

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“…As the polarization can be coupled with other intrinsic properties as well as external stimuli, the ferroelectric exhibits various physical properties, and is considered as a critical component in modern and future electronic elements. [ 14 , 15 , 16 , 17 , 18 , 19 ] As shown in Figure 1b , under the external stimuli of electric, stress, light, and magnetic fields, the ferroelectric enjoys multiple coupling effects of piezoelectric, [ 20 ] electric‐optic, [ 21 , 22 , 23 ] magneto‐electric, [ 24 , 25 ] piezo‐magnetic, [ 26 ] and magneto‐optic [ 27 ] effects, among others. [ 28 , 29 , 30 ] Based on these unusual physical properties, the ferroelectric materials have been employed for widespread applications such as pyroelectric sensors, piezoelectric actuators, electro‐optic modulators, and nonvolatile memories, [ 28 , 29 , 30 ] and other novel applications following the exploration of unusual polarization domain structures have also been conceived.…”

Section: Introductionmentioning

confidence: 99%

Probing Ultrafast Dynamics of Ferroelectrics by Time‐Resolved Pump‐Probe Spectroscopy

et al. 2021

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Ferroelectric materials have been a key research topic owing to their wide variety of modern electronic and photonic applications. For the quick exploration of higher operating speed, smaller size, and superior efficiencies of novel ferroelectric devices, the ultrafast dynamics of ferroelectrics that directly reflect their respond time and lifetimes have drawn considerable attention. Driven by time-resolved pump-probe spectroscopy that allows for probing, controlling, and modulating dynamic processes of ferroelectrics in real-time, much research efforts have been made to understand and exploit the ultrafast dynamics of ferroelectric. Herein, the current state of ultrafast dynamic features of ferroelectrics tracked by time-resolved pump-probe spectroscopy is reviewed, which includes ferroelectrics order parameters of polarization, lattice, spin, electronic excitation, and their coupling. Several potential perspectives and possible further applications combining ultrafast pump-probe spectroscopy and ferroelectrics are also presented. This review offers a clear guidance of ultrafast dynamics of ferroelectric orders, which may promote the rapid development of next-generation devices.

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Atomic-scale observations of electrical and mechanical manipulation of topological polar flux closure

Cited by 57 publications

References 44 publications

Charged Domain Wall and Polar Vortex Topologies in a Room Temperature Magnetoelectric Multiferroic Thin Film

Charged Domain Wall and Polar Vortex Topologies in a Room Temperature Magnetoelectric Multiferroic Thin Film

Recent Advances in Multilayer‐Structure Dielectrics for Energy Storage Application

Probing Ultrafast Dynamics of Ferroelectrics by Time‐Resolved Pump‐Probe Spectroscopy

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