This paper reports a versatile template-free
method based on the
hydrogen reduction of metallic salts for the synthesis of nanoporous
Ni and alloys. The approach involves thermal decomposition and reduction
of metallic precursors followed with metal cluster nucleation and
ligament growth. Topological disordered porous architectures of metals
with a controllable distribution of pore size and ligament size ranging
from tens of nanometers to micrometers are synthesized. The reduction
processes are scrutinized through X-ray diffraction, scanning electron
microscopy, and transmission electron microscopy. The formation mechanism
of the nanoporous metal is qualitatively explained. The as-prepared
nanoporous Ni was tested as binder-free current collectors for nickel
oxalate anodes of lithium ion batteries. The nanoporous Ni electrodes
deliver enhanced reversible capacities and cyclic performances compared
with commercial Ni foam. It is confirmed that this synthesis method
has versatility not only because it is suitable for different types
of metallic salts precursors but also for various other metals and
alloys.
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