As an anode material
for sodium-ion batteries (SIBs), hard carbon
(HC) presents high specific capacity and favorable cycling performance.
However, high cost and low initial Coulombic efficiency (ICE) of HC
seriously limit its future commercialization for SIBs. A typical biowaste,
mangosteen shell was selected as a precursor to prepare low-cost and
high-performance HC via a facile one-step carbonization method, and
the influence of different heat treatments on the morphologies, microstructures,
and electrochemical performances was investigated systematically. The microstructure evolution studied using X-ray diffraction, Raman,
Brunauer–Emmett–Teller, and high-resolution transmission
electron microscopy, along with electrochemical measurements, reveals
the optimal carbonization condition of the mangosteen shell: HC carbonized
at 1500 °C for 2 h delivers the highest reversible capacity of
∼330 mA h g
–1
at a current density of 20
mA g
–1
, a capacity retention of ∼98% after
100 cycles, and an ICE of ∼83%. Additionally, the sodium-ion
storage behavior of HC is deeply analyzed using galvanostatic intermittent
titration and cyclic voltammetry technologies.
Molecular junctions (MJs) represent an ideal platform for studying charge and energy transport at the atomic and molecular scale and are of fundamental interest for the development of molecular‐scale electronics. While tremendous efforts have been devoted to probing charge transport in MJs during the past two decades, only recently advances in experimental techniques and computational tools have made it possible to precisely characterize how heat is transported, dissipated, and converted in MJs. This progress is central to the design of thermally robust molecular circuits and high‐efficiency energy conversion devices. In addition, thermal and thermoelectric studies on MJs offer unique opportunities to test the validity of classical physical laws at the nanoscale. A brief survey of recent progress and emerging experimental approaches in probing thermal and thermoelectric transport in MJs is provided, including thermal conduction, heat dissipation, and thermoelectric effects, from both a theoretical and experimental perspective. Future directions and outstanding challenges in the field are also discussed.
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