posted on 2023-10-30, 22:15authored byShiyu Ji, Di Peng, Fang Sun, Qing You, Runguo Wang, Nan Yan, Yue Zhou, Weiyi Wang, Qing Tang, Nan Xia, Zhi Zeng, Zhikun Wu
Understanding charge transport among
metal particles
with sizes
of approximately 1 nm poses a great challenge due to the ultrasmall
nanosize, yet it holds great significance in the development of innovative
materials as substitutes for traditional semiconductors, which are
insulative and unstable in less than ∼10 nm thickness. Herein,
atomically precise gold nanoclusters with well-defined compositions
and structures were investigated to establish a mathematical relation
between conductivity and interparticle distance. This was accomplished
using high-pressure in situ resistance characterizations, synchrotron
X-ray diffraction (XRD), and the Murnaghan equation of state. Based
on this precise correlation, it was predicted that the conductivity
of Au25(SNap)18 (SNap: 1-naphthalenethiolate)
solid is comparable to that of bulk silver when the interparticle
distance is reduced to approximately 3.6 Å. Furthermore, the
study revealed the coexisting, competing tunneling, and incoherent
hopping charge transport mechanisms, which differed from those previously
reported. The introduction of conjugation-structured ligands, tuning
of the structures of metal nanoclusters, and use of high-pressure
techniques contributed to enhanced conductivity, and thus, the charge
carrier types were determined using Hall measurements. Overall, this
study provides valuable insight into the charge transport in gold
nanocluster solids and represents an important advancement in metal
nanocluster semiconductor research.