2021
DOI: 10.1007/s12274-021-3644-0
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Asymmetric interfaces and high-TC ferromagnetic phase in La0.67Ca0.33MnO3/SrRuO3 superlattices

Abstract: Interfacial magnetism in functional oxide heterostructures not only exhibits intriguing physical phenomena but also implies great potential for device applications. In these systems, interfacial structural and electronic reconstructions are essential for improving the stability and tunability of the magnetic properties. In this work, we constructed ultra-thin La 0.67 Ca 0.33 MnO 3 (LCMO) and SrRuO 3 (SRO) layers into superlattices, which exhibited a robust ferromagnetic phase. The high Curie temperature (T C )… Show more

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Cited by 7 publications
(4 citation statements)
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“…The exchange integral is proportional to the bond angle of Mn 3+ –O–Mn 4+ . Therefore, the decrease of the modulation thickness can enhance the interfacial tensile strain and bond angle of Mn 3+ –O–Mn 4+ , which is beneficial to strengthen the ferromagnetic double-exchange interaction and T c . ,, In addition, the cationic interdiffusion at the LCMO/SRO interface could occur, which usually can not be avoided in the epitaxy by pulsed laser deposition at high temperatures and can result in the transformation of magnetic properties. For the SRO layer, the decreased temperature of the magnetic ordering is expected via the La, Ca, or Mn doping according to the previous literature. In the LCMO, the Sr diffusion from SRO can contribute to higher T c , benefiting from the optimized tolerance factor between two neighboring Mn, which was consistent with our observation of enhanced T c at the LCMO/SRO interface.…”
Section: Results and Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…The exchange integral is proportional to the bond angle of Mn 3+ –O–Mn 4+ . Therefore, the decrease of the modulation thickness can enhance the interfacial tensile strain and bond angle of Mn 3+ –O–Mn 4+ , which is beneficial to strengthen the ferromagnetic double-exchange interaction and T c . ,, In addition, the cationic interdiffusion at the LCMO/SRO interface could occur, which usually can not be avoided in the epitaxy by pulsed laser deposition at high temperatures and can result in the transformation of magnetic properties. For the SRO layer, the decreased temperature of the magnetic ordering is expected via the La, Ca, or Mn doping according to the previous literature. In the LCMO, the Sr diffusion from SRO can contribute to higher T c , benefiting from the optimized tolerance factor between two neighboring Mn, which was consistent with our observation of enhanced T c at the LCMO/SRO interface.…”
Section: Results and Discussionmentioning
confidence: 99%
“…Therefore, the decrease of the modulation thickness can enhance the interfacial tensile strain and bond angle of Mn 3+ −O−Mn 4+ , which is beneficial to strengthen the ferromagnetic double-exchange interaction and T c . 21,40,41 In addition, the cationic interdiffusion at the LCMO/SRO interface could occur, which usually can not be avoided in the epitaxy by pulsed laser deposition at high temperatures and can result in the transformation of magnetic properties. For the SRO layer, the decreased temperature of the magnetic ordering is expected via the La, Ca, or Mn doping according to the previous literature.…”
Section: ■ Results and Discussionmentioning
confidence: 99%
“…Table 2 summarizes the reported SrRuO 3 based superlattices with various functional partner compounds. [ 41,54,55,70,86–164 ] Herein, several emergent functionalities of SrRuO 3 based superlattices and their modulations are reviewed in the following Sections.…”
Section: D Srruo3 Based Superlatticesmentioning
confidence: 99%
“…Specifically, the twist angle and lattice shift between HS layers provide an effective method to alter interlayer interactions, which can be done by varying the interlayer distance . For this reason, this method can be used to modulate and affect electronic properties of materials, leading to the induction of new quantum phenomena, including superconductivity, magnetism, and insulating states. , Practically, the application of hydrostatic pressure by a diamond anvil cell (DAC) has been proven to be another tool to control interlayer interactions and thus achieve electronic transitions in 2D TMDs and HSs. , Indeed, hydrostatic pressure can considerably reduce distances between atoms and modify the nature of their interactions. Furthermore, interlayer interactions are much weaker than intralayer covalent bonds, which makes it possible to modulate them much more efficiently than intralayer interactions by compression.…”
Section: Introductionmentioning
confidence: 99%