Chiral molecular intercalation superlattices

Qian, Qi; Ren, Huaying; Zhou, Jingyuan; Wan, Zhong; Zhou, Jingxuan; Yan, Xingxu; Cai, Jin; Wang, Peiqi; Li, Bailing; Sofer, Zdeněk; Li, Bo; Duan, Xidong; Pan, Xiaoqing; Huang, Yu; Duan, Xiangfeng

doi:10.1038/s41586-022-04846-3

Cited by 91 publications

(93 citation statements)

References 63 publications

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“…Due to the confinement of their crystalline structure and active sites in 2D, the molecular reaction dynamics and the catalytic activity of such systems can be modeled and predicted by theoretical calculations more easily. In 2D catalysts consisting of monolayers or very few layers, the chiral molecules can be placed below the layer, like in the case of monolayer NiOx [39] or in between the layers [75] , to spin-polarize the surface of 2D material from below. Such configurations are expected to be more mechanically and electrochemically stable since the molecules are protected from the electrolyte.…”

Section: Two-dimensional Materials As Ideal Model Systemsmentioning

confidence: 99%

“…In those conditions, chiral molecules might not be particularly stable physically and/or electrochemically. Therefore, we need to further explore the possibility of protecting, i.e., encapsulating, these molecules into matrices, or between the layers of catalytically active 2D materials [75] . For future development of CISS based catalysts, it is crucial also to establish a strong collaboration between experimentalists and theoreticians.…”

Section: Two-dimensional Materials As Ideal Model Systemsmentioning

confidence: 99%

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Spin-control in electrocatalysis for clean energy

Liang

Lihter

Lingenfelder

2022

Preprint

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A sustainable future demands a successful transition from a carbon-energy dependent economy towards renewable energy schemes, many of which ultimately rely on the development of efficient electrocatalysis that either converts chemical energy into electricity or uses electrons to produce chemical energy. In general, electrocatalysis studies focus on the interactions (e.g., electron transfer) between the catalyst surface and the reaction intermediates. However, the role of electron spin, as an intrinsic property of electrons, has commonly been overlooked. Recently, controlling the electron spin polarization at the catalyst’s surface demonstrated the great potential of boosting both reaction activity and product selectivity. Molecule-induced electron spin polarization inspired by the chiral-induced spin selectivity (CISS) effect has started to have a remarkable impact in electrocatalysis. In this compact review, we summarize the latest studies that use molecule-induced electron spin polarization to enhance catalytic performance. We focus on the reactions essential to the so-called hydrogen economy, and discuss the feasibility and limitations of this effect. Finally, we share our perspective regarding the more impactful future applications.

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Section: Two-dimensional Materials As Ideal Model Systemsmentioning

confidence: 99%

Section: Two-dimensional Materials As Ideal Model Systemsmentioning

confidence: 99%

Spin-control in electrocatalysis for clean energy

Liang

Lihter

Lingenfelder

2022

Preprint

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“…The latter are especially powerful as they represent two complementary goals of the field: developing quantum hardware to learn about quantum materials, and developing quantum materials that in turn improve quantum hardware. Chemical approaches, similarly, present advantages for quantum information science by advancing the use of precisely controlled molecules as qubits as we have seen in recent papers on the robust molecular assembly of novel chiral synthetic molecules and functionalized 2D materials optimized for long spin-coherence times. , …”

Section: Recent Newsmentioning

confidence: 99%

“…Chemical approaches, similarly, present advantages for quantum information science by advancing the use of precisely controlled molecules as qubits as we have seen in recent papers on the robust molecular assembly of novel chiral synthetic molecules and functionalized 2D materials optimized for long spin-coherence times. 14,15 Just as new tools opened up exploration of new worlds in biotechnology and nanoscience, so too will new capabilities and new questions come into being through the development of new tools in quantum materials and devices, whether they are experimental, theoretical, or simulations. The nano community has important roles to play in their development.…”

mentioning

confidence: 99%

Quantum Materials and Devices at ACS Nano

Narang¹,

Weiss²

2022

ACS Nano

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“…It has been observed in electron transport, electron transfer, electron polarization, and in electron photoemission, involving biomolecules, organic molecules and also inorganic solids, with efficiencies of up to 80-90%. [10][11][12][13][14][15][16] It has implications for spintronics, enantioselective reactions, long-range charge transport in biological molecules, chiral recognition in intermolecular interactions, 17,18 and quantum information science. 4,5,10,[19][20][21][22][23] The mechanism behind CISS is not understood at present, although it is clear that it is related to the interplay of spaceand time-reversal-symmetry breaking and spin-orbit coupling (SOC).…”

mentioning

confidence: 99%

Chiral-Induced Spin Selectivity and Non-equilibrium Spin Accumulation in Molecules and Interfaces: A First-Principles Study

Naskar

Mújica

Herrmann

2022

Preprint

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Electrons moving through chiral molecules are selected according to their spin orientation and the helicity of the molecule, an effect known as chiral induced spin selectivity (CISS). The underlying physical mechanism is not yet completely understood. To help elucidate this mechanism, a non-equilibrium Green’s function method, combined with a Landauer approach and density functional theory, is applied to carbon helices contacted by gold electrodes, resulting in spin polarization of transmitted electrons. Interestingly, spin polarization is also observed in the non-equilibrium electronic structure of the junctions. While this spin polarization is small, its sign changes with the direction of current and with the handedness of the molecule. While these calculations were performed with a pure exchange-correlation functional, previous studies suggest that computationally more expensive hybrid functionals may lead to considerably larger spin polarization in the electronic structure. Thus, nonequilibrium spin polarization could be a key component in understanding the CISS mechanism.

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Chiral molecular intercalation superlattices

Cited by 91 publications

References 63 publications

Spin-control in electrocatalysis for clean energy

Spin-control in electrocatalysis for clean energy

Quantum Materials and Devices at ACS Nano

Chiral-Induced Spin Selectivity and Non-equilibrium Spin Accumulation in Molecules and Interfaces: A First-Principles Study

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