Chem. J. Chinese Universities ›› 2019, Vol. 40 ›› Issue (5): 980.doi: 10.7503/cjcu20180804
• Physical Chemistry • Previous Articles Next Articles
ZHI Shasha1, BAN Ying1, XU Zhiguang1, XU Xuan1,2,3,*()
Received:
2018-11-28
Online:
2019-04-04
Published:
2019-04-04
Contact:
XU Xuan
E-mail:xuxuan@scnu.edu.cn
Supported by:
CLC Number:
TrendMD:
ZHI Shasha,BAN Ying,XU Zhiguang,XU Xuan. Electron Transport of Metal String Complexes of [MM'M″(dpa)4(Cl)2](M=Co, Ni; M',M″=Co, Rh)†[J]. Chem. J. Chinese Universities, 2019, 40(5): 980.
Fig.4 Transmission spectra of complex 1 under the potential of 0 V(A), 0.1 V(B), 0.2 V(C), 0.3 V(D) and 0.5 V(E) Fermi energy is set to be 0. Black and red line denote the spin-α and spin-β manifolds, respectively.
Fig.5 Transmission spectra of complex 2 under the potential of -0.5 V(A), -0.3 V(B), -0.2 V(C), 0 V(D), 0.2 V(E), 0.3 V(F) and 0.5 V(G) Fermi energy is set to be 0. Black and red line denote the spin-α and spin-β manifolds, respectively.
Fig.6 Transmission spectra of complex 3 under the potential of -0.5 V(A), -0.3 V(B), -0.2 V(C), 0 V(D), 0.2 V(E), 0.3 V(F) and 0.5 V(G) Fermi energy is set to be 0. Black and red line denote the spin-α and spin-β manifolds, respectively.
Fig.7 Transmission spectra of complex 4 under the potential of -0.5 V(A), -0.3 V(B), -0.2 V(C), 0 V(D), 0.2 V(E), 0.3 V(F) and 0.5 V(G) Fermi energy is set to be 0. Black and red line denote the spin-α and spin-β manifolds, respectively.
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