Liu, L., Song, X., Dai, J., Yang, H., Chen, Y., Huang, X., Huang, Z., Ji, H., Zhang, Y., Wu, X., Sun, J. T., Zhang, Q., Zhou, J., Huang, Y., Qiao, J., Ji, W., Gao, H. J., & Wang, Y. (2023). Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence. ACS Nano, 17(3), 2702-2710. https://doi.org/10.1021/acsnano.2c10841
Liu, Liwei ; Song, Xuan ; Dai, Jiaqi et al. / Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence. In: ACS Nano. 2023 ; Vol. 17, No. 3. pp. 2702-2710.
@article{f994cce69c8443dca44f45659d94a517,
title = "Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence",
abstract = "Layered charge-density-wave (CDW) materials have gained increasing interest due to their CDW stacking-dependent electronic properties for practical applications. Among the large family of CDW materials, those with star of David (SOD) patterns are very important due to the potentials for quantum spin liquid and related device applications. However, the spatial extension and the spin coupling information down to the nanoscale remain elusive. Here, we report the study of heterochiral CDW stackings in bilayer (BL) NbSe2 with high spatial resolution. We reveal that there exist well-defined heterochiral stackings, which have inhomogeneous electronic states among neighboring CDW units (star of David, SOD), significantly different from the homogeneous electronic states in the homochiral stackings. Intriguingly, the different electronic behaviors are spatially localized within each SOD with a unit size of 1.25 nm, and the gap sizes are determined by the different types of SOD stackings. Density functional theory (DFT) calculations match the experimental measurements well and reveal the SOD-stacking-dependent correlated electronic states and antiferromagnetic/ferromagnetic couplings. Our findings give a deep understanding of the spatial distribution of interlayer stacking and the delicate modulation of the spintronic states, which is very helpful for CDW-based nanoelectronic devices.",
keywords = "chiral CDW lattice, scanning tunneling microscopy, spin interaction, stacking materials, twistronics",
author = "Liwei Liu and Xuan Song and Jiaqi Dai and Han Yang and Yaoyao Chen and Xinyu Huang and Zeping Huang and Hongyan Ji and Yu Zhang and Xu Wu and Sun, {Jia Tao} and Quanzhen Zhang and Jiadong Zhou and Yuan Huang and Jingsi Qiao and Wei Ji and Gao, {Hong Jun} and Yeliang Wang",
note = "Publisher Copyright: {\textcopyright} 2023 American Chemical Society.",
year = "2023",
month = feb,
day = "14",
doi = "10.1021/acsnano.2c10841",
language = "English",
volume = "17",
pages = "2702--2710",
journal = "ACS Nano",
issn = "1936-0851",
publisher = "American Chemical Society",
number = "3",
}
Liu, L, Song, X, Dai, J, Yang, H, Chen, Y, Huang, X, Huang, Z, Ji, H, Zhang, Y, Wu, X, Sun, JT, Zhang, Q, Zhou, J, Huang, Y, Qiao, J, Ji, W, Gao, HJ & Wang, Y 2023, 'Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence', ACS Nano, vol. 17, no. 3, pp. 2702-2710. https://doi.org/10.1021/acsnano.2c10841
Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence. /
Liu, Liwei; Song, Xuan; Dai, Jiaqi et al.
In:
ACS Nano, Vol. 17, No. 3, 14.02.2023, p. 2702-2710.
Research output: Contribution to journal › Article › peer-review
TY - JOUR
T1 - Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence
AU - Liu, Liwei
AU - Song, Xuan
AU - Dai, Jiaqi
AU - Yang, Han
AU - Chen, Yaoyao
AU - Huang, Xinyu
AU - Huang, Zeping
AU - Ji, Hongyan
AU - Zhang, Yu
AU - Wu, Xu
AU - Sun, Jia Tao
AU - Zhang, Quanzhen
AU - Zhou, Jiadong
AU - Huang, Yuan
AU - Qiao, Jingsi
AU - Ji, Wei
AU - Gao, Hong Jun
AU - Wang, Yeliang
N1 - Publisher Copyright:
© 2023 American Chemical Society.
PY - 2023/2/14
Y1 - 2023/2/14
N2 - Layered charge-density-wave (CDW) materials have gained increasing interest due to their CDW stacking-dependent electronic properties for practical applications. Among the large family of CDW materials, those with star of David (SOD) patterns are very important due to the potentials for quantum spin liquid and related device applications. However, the spatial extension and the spin coupling information down to the nanoscale remain elusive. Here, we report the study of heterochiral CDW stackings in bilayer (BL) NbSe2 with high spatial resolution. We reveal that there exist well-defined heterochiral stackings, which have inhomogeneous electronic states among neighboring CDW units (star of David, SOD), significantly different from the homogeneous electronic states in the homochiral stackings. Intriguingly, the different electronic behaviors are spatially localized within each SOD with a unit size of 1.25 nm, and the gap sizes are determined by the different types of SOD stackings. Density functional theory (DFT) calculations match the experimental measurements well and reveal the SOD-stacking-dependent correlated electronic states and antiferromagnetic/ferromagnetic couplings. Our findings give a deep understanding of the spatial distribution of interlayer stacking and the delicate modulation of the spintronic states, which is very helpful for CDW-based nanoelectronic devices.
AB - Layered charge-density-wave (CDW) materials have gained increasing interest due to their CDW stacking-dependent electronic properties for practical applications. Among the large family of CDW materials, those with star of David (SOD) patterns are very important due to the potentials for quantum spin liquid and related device applications. However, the spatial extension and the spin coupling information down to the nanoscale remain elusive. Here, we report the study of heterochiral CDW stackings in bilayer (BL) NbSe2 with high spatial resolution. We reveal that there exist well-defined heterochiral stackings, which have inhomogeneous electronic states among neighboring CDW units (star of David, SOD), significantly different from the homogeneous electronic states in the homochiral stackings. Intriguingly, the different electronic behaviors are spatially localized within each SOD with a unit size of 1.25 nm, and the gap sizes are determined by the different types of SOD stackings. Density functional theory (DFT) calculations match the experimental measurements well and reveal the SOD-stacking-dependent correlated electronic states and antiferromagnetic/ferromagnetic couplings. Our findings give a deep understanding of the spatial distribution of interlayer stacking and the delicate modulation of the spintronic states, which is very helpful for CDW-based nanoelectronic devices.
KW - chiral CDW lattice
KW - scanning tunneling microscopy
KW - spin interaction
KW - stacking materials
KW - twistronics
UR - http://www.scopus.com/inward/record.url?scp=85146894653&partnerID=8YFLogxK
U2 - 10.1021/acsnano.2c10841
DO - 10.1021/acsnano.2c10841
M3 - Article
C2 - 36661840
AN - SCOPUS:85146894653
SN - 1936-0851
VL - 17
SP - 2702
EP - 2710
JO - ACS Nano
JF - ACS Nano
IS - 3
ER -
Liu L, Song X, Dai J, Yang H, Chen Y, Huang X et al. Unveiling Electronic Behaviors in Heterochiral Charge-Density-Wave Twisted Stacking Materials with 1.25 nm Unit Dependence. ACS Nano. 2023 Feb 14;17(3):2702-2710. doi: 10.1021/acsnano.2c10841
