Your search keyword '"Wang, Yujia"' showing total 9 results

1. Influence of N,N,N-trimethyl-1-adamantyl ammonium (TMAda+) Structure Directing Agent on Al Pair Distributions and Features in Chabazite Zeolite

Author

Wang, Xiaoyu, Wang, Yujia, Moini, Ahmad, Gounder, Rajamani, Maginn, Edward J., and Schneider, William F.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

While organic structure directing agents (OSDAs) are well known to have a directional influence on the topology of a crystallizing zeolite, the relationship between OSDA charge and siting of aliovalent ions on a primarily siliceous framework is unclear. Here, we explore the relationship between OSDA orientation, Al3+ siting, and lattice energy, taking as a model system CHA zeolite occluded with N,N,N-trimethyl-1-adamantyl ammonium (TMAda+) at an Si/Al ratio of 11/1. We use density functional theory calculations to parametrize a fixed-charge classical model describing van der Waals and electrostatic interactions between framework and OSDA. We enumerate and explore all possible combinations of OSDA orientation and Al location (attending to Lowenstein's rule) within a 36 T-site supercell. We find that interaction energies vary over 60 kJ/double-six-ring-unit (d6r). Further, analysis of configurations reveals that energies are sensitive to Al-Al proximity, such that low energies are associated with Al3+ pairs in 8-membered rings and higher energies associated with Al3+ pairs in smaller 6- and 4-membered rings. Comparisons with Al siting inferred from CHA zeolite crystallized with TMAda+ suggests that these computed interaction energies are useful reporters of observed Al siting in CHA synthesized with TMAda+.

Published

2021

2. Robust ferromagnetism in highly strained SrCoO3 thin films

Author

Wang, Yujia, He, Qing, Ming, Wenmei, Du, Mao-Hua, Lu, Nianpeng, Cafolla, Clodomiro, Fujioka, Jun, Zhang, Qinghua, Zhang, Ding, Shen, Shengchun, Lyu, Yingjie, N'Diaye, Alpha T., Arenholz, Elke, Gu, Lin, Nan, Cewen, Tokura, Yoshinori, Okamoto, Satoshi, and Yu, Pu

Subjects

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

Abstract

Epitaxial strain provides important pathways to control the magnetic and electronic states in transition metal oxides. However, the large strain is usually accompanied by a strong reduction of the oxygen vacancy formation energy, which hinders the direct manipulation of their intrinsic properties. Here using a post-deposition ozone annealing method, we obtained a series of oxygen stoichiometric SrCoO3 thin films with the tensile strain up to 3.0%. We observed a robust ferromagnetic ground state in all strained thin films, while interestingly the tensile strain triggers a distinct metal to insulator transition along with the increase of the tensile strain. The persistent ferromagnetic state across the electrical transition therefore suggests that the magnetic state is directly correlated with the localized electrons, rather than the itinerant ones, which then calls for further investigation of the intrinsic mechanism of this magnetic compound beyond the double-exchange mechanism.

Published

2020

3. Emergent electric field control of phase transformation in oxide superlattices

Author

Yi, Di, Wang, Yujia, Erve, Olaf M. J. van 't, Xu, Liubin, Yuan, Hongtao, Veit, Michael J., Balakrishnan, Purnima P., Choi, Yongseong, N'Diaye, Alpha T., Shafer, Padraic, Arenholz, Elke, Grutter, Alexander, Xu, Haixuan, Yu, Pu, Jonker, Berend T., and Suzuki, Yuri

Subjects

Condensed Matter - Materials Science

Abstract

Electric fields can transform materials with respect to their structure and properties, enabling various applications ranging from batteries to spintronics. Recently electrolytic gating, which can generate large electric fields and voltage-driven ion transfer, has been identified as a powerful means to achieve electric-field-controlled phase transformations. The class of transition metal oxides (TMOs) provide many potential candidates that present a strong response under electrolytic gating. However, very few show a reversible structural transformation at room-temperature. Here, we report the realization of a digitally synthesized TMO that shows a reversible, electric-field-controlled transformation between distinct crystalline phases at room-temperature. In superlattices comprised of alternating one-unit-cell of SrIrO3 and La0.2Sr0.8MnO3, we find a reversible phase transformation with a 7% lattice change and dramatic modulation in chemical, electronic, magnetic and optical properties, mediated by the reversible transfer of oxygen and hydrogen ions. Strikingly, this phase transformation is absent in the constituent oxides, solid solutions and larger period superlattices. Our findings open up a new class of materials for voltage-controlled functionality.

Published

2020

4. Evidence of charge density wave with anisotropic gap in monolayer VTe$_2$ film

Author

Wang, Yuan, Ren, Junhai, Li, Jiaheng, Wang, Yujia, Peng, Huining, Yu, Pu, Duan, Wenhui, and Zhou, Shuyun

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report experimental evidence of charge density wave (CDW) transition in monolayer 1T-VTe$_2$ film. 4$\times$4 reconstruction peaks are observed by low energy electron diffraction below the transition temperature $T_{CDW}$ = 186 K. Angle-resolved photoemission spectroscopy measurements reveal arc-like pockets with anisotropic CDW gaps up to 50 meV. The anisotropic CDW gap is attributed to the imperfect nesting of the CDW wave vector, and first-principles calculations reveal phonon softening at the same vector, suggesting the important roles of Fermi surface nesting and electron-phonon interaction in the CDW mechanism.

Published

2019

5. A protonated brownmillerite electrolyte for superior low-temperature proton conductivity

Author

Lu, Nianpeng, Wang, Yujia, Qiao, Shuang, Li, Hao-Bo, He, Qing, Li, Zhuolu, Wang, Meng, Zhang, Jingzhao, Tsang, Sze Chun, Guo, Jingwen, Yang, Shuzhen, Zhang, Jianbing, Deng, Ke, Zhang, Ding, Ma, Jing, Wu, Yang, Zhu, Junyi, Tokura, Yoshinori, Nan, Ce-Wen, Wu, Jian, and Yu, Pu

Subjects

Condensed Matter - Materials Science

Abstract

Design novel solid oxide electrolyte with enhanced ionic conductivity forms one of the Holy Grails in the field of materials science due to its great potential for wide range of energy applications. Conventional solid oxide electrolyte typically requires elevated temperature to activate the ionic transportation, while it has been increasing research interests to reduce the operating temperature due to the associated scientific and technological importance. Here, we report a conceptually new solid oxide electrolyte, HSrCoO2.5, which shows an exceptional enhanced proton conductivity at low temperature region (from room temperature to 140 oC). Combining both the experimental results and corresponding first-principles calculations, we attribute these intriguing properties to the extremely-high proton concentration as well as the well-ordered oxygen vacancy channels inherited from the novel crystalline structure of HSrCoO2.5. This result provides a new strategy to design novel solid oxide electrolyte with excellent proton conductivity for wide ranges of energy-related applications.

Published

2018

6. Electric-field Control of Magnetism with Emergent Topological Hall Effect in SrRuO3 through Proton Evolution

Author

Li, Zhuolu, Shen, Shengchun, Tian, Zijun, Hwangbo, Kyle, Wang, Meng, Wang, Yujia, Bartram, F. Michael, He, Liqun, Lyu, Yingjie, Dong, Yongqi, Wan, Gang, Li, Haobo, Lu, Nianpeng, Zhou, Hua, Arenholz, Elke, He, Qing, Yang, Luyi, Luo, Weidong, and Yu, Pu

Subjects

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

Abstract

Ionic substitution forms an essential pathway to manipulate the carrier density and crystalline symmetry of materials via ion-lattice-electron coupling, leading to a rich spectrum of electronic states in strongly correlated systems. Using the ferromagnetic metal SrRuO3 as a model system, we demonstrate an efficient and reversible control of both carrier density and crystalline symmetry through the ionic liquid gating induced protonation. The insertion of protons electron-dopes SrRuO3, leading to an exotic ferromagnetic to paramagnetic phase transition along with the increase of proton concentration. Intriguingly, we observe an emergent topological Hall effect at the boundary of the phase transition as the consequence of the newly-established Dzyaloshinskii-Moriya interaction owing to the breaking of inversion symmetry in protonated SrRuO3 with the proton compositional film-depth gradient. We envision that electric-field controlled protonation opens a novel strategy to design material functionalities.

Published

2018

7. Anomalous Hall Effect and Spin Fluctuations in Ionic Liquid Gated SrCoO$_3$ Thin Films

Author

Zhang, Ding, Ishizuka, Hiroaki, Lu, Nianpeng, Wang, Yujia, Nagaosa, Naoto, Yu, Pu, and Xue, Qi-Kun

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The recent realization of epitaxial SrCoO$_3$ thin films has triggered a renewed interest in their electronic, magnetic, and ionic properties. Here we uncover several unusual magneto-transport properties of this compound, suggesting that it hosts persistent spin fluctuation down to low temperatures. We achieve the metallic SrCoO$_3$ with record-low resistivity from insulating SrCoO$_{2.5}$ by the ionic liquid gating. We find a linear relationship between the anomalous Hall resistivity and the longitudinal resistivity, which cannot be accounted for by the conventional mechanisms. We theoretically propose that the impurity induced chiral spin fluctuation gives rise to such a dependence. The existence of spin fluctuation manifests itself as negatively enhanced magneto-resistance of SrCoO$_3$ when the temperature approaches zero. Our study brings further insight into the unique spin state of SrCoO$_3$ and unveils a novel skew scattering mechanism for the anomalous Hall effect., Comment: 8 pages, 9 figures

Published

2018

8. High density array of epitaxial BiFeO3 nanodots with robust and reversibly switchable topological domain states

Author

Li, Zhongwen, Wang, Yujia, Tian, Guo, Li, Peilian, Zhao, Lina, Zhang, Fengyuan, Yao, Junxiang, Fan, Hua, Song, Xiao, Chen, Deyang, Fan, Zhen, Qin, Minghui, Zeng, Min, Zhang, Zhang, Lu, Xubing, Hu, Shejun, Lei, Chihou, Zhu, Qingfeng, Li, Jiangyu, Gao, Xingsen, and Liu, Jun-Ming

Subjects

Condensed Matter - Materials Science

Abstract

The exotic topological domains in ferroelectrics and multiferroics have attracted extensive interest in recent years due to their novel functionalities and potential applications in nanoelectronic devices. One of the key challenges for such applications is a realization of robust yet reversibly switchable nanoscale topological domain states with high density, wherein spontaneous topological structures can be individually addressed and controlled. This has been accomplished in our work using high density arrays of epitaxial BiFeO3 (BFO) nanodots with lateral size as small as ~60 nm. We demonstrate various types of spontaneous topological domain structures, including center-convergent domains, center-divergent domains, and double-center domains, which are stable over sufficiently long time yet can be manipulated and reversibly switched by electric field. The formation mechanisms of these topological domain states, assisted by the accumulation of compensating charges on the surface, have also been revealed. These result demonstrated that these reversibly switchable topological domain arrays are promising for applications in high density nanoferroelectric devices such as nonvolatile memories, Comment: 5 figures, 18 pages, plus supplementary materials

Published

2017

9. Modeled Influence of a Structure Directing Agent on Al Siting Energetics: N,N,N-trimethyl-1-adamantyl ammonium (TMAda+) in Chabazite

Author

Wang, Xiaoyu, Wang, Yujia, Moini, Ahmad, Gounder, Rajamani, Maginn, Edward J., and Schneider, William F.

Subjects

Chemical Physics (physics.chem-ph), Condensed Matter - Materials Science, Physics - Chemical Physics, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences

Abstract

While organic structure directing agents (OSDAs) are well known to have a directional influence on the topology of a crystallizing zeolite, the relationship between OSDA charge and siting of aliovalent ions on a primarily siliceous framework is unclear. Here, we explore the relationship between OSDA orientation, Al3+ siting, and lattice energy, taking as a model system CHA zeolite occluded with N,N,N-trimethyl-1-adamantyl ammonium (TMAda$^+$) at an Si/Al ratio of 11/1. We use density functional theory calculations to parametrize a fixed-charge classical model describing van der Waals and electrostatic interactions between framework and OSDA. We enumerate and explore all possible combinations of OSDA orientation and Al location (attending to Lowenstein's rule) within a 36 T-site supercell. We find that interaction energies vary over 60 kJ/double-six-ring-unit (d6r). Further, analysis of configurations reveals that energies are sensitive to Al-Al proximity, such that low energies are associated with Al3+ pairs in 8-membered rings and higher energies associated with Al3+ pairs in smaller 6- and 4-membered rings. Comparisons with Al siting inferred from CHA zeolite crystallized with TMAda$^+$ suggests that these computed interaction energies are useful reporters of observed Al siting in CHA synthesized with TMAda+.

Published

2021