3 research outputs found
Polyaniline Induced Trivalent Ni in Laser-Fabricated Nickel Oxides for Efficient Oxygen Evolution Reaction
Although it is generally acknowledged that transition
metals at
high oxidation states represent superior oxygen evolution reaction
(OER) activity, the preparation and stability of such a high-valence
state are still a challenge, which requires relatively harsh reaction
conditions and is unstable under ambient conditions. Herein, we report
the formation of trivalent nickel (Ni3+) in laser-fabricated
nickel oxides induced by polyaniline (PANI) under electrochemical
activation via a significant charge transfer between Ni and N, as
confirmed by X-ray photoelectron spectroscopy and density functional
theory calculations. Thereafter, the presence of Ni3+ and
the improved conductivity by PANI effectively increase the electrochemical
OER activity of the samples together with excellent long-term stability.
This work provides new insights for the rational manufacture of high-valence
metal for electrochemical reactions
Bosonic Confinement and Coherence in Disordered Nanodiamond Arrays
In
the presence of disorder, superconductivity exhibits short-range
characteristics linked to localized Cooper pairs which are responsible
for anomalous phase transitions and the emergence of quantum states
such as the bosonic insulating state. Complementary to well-studied
homogeneously disordered superconductors, superconductor-normal hybrid
arrays provide tunable realizations of the degree of granular disorder
for studying anomalous quantum phase transitions. Here, we investigate
the superconductor–bosonic dirty metal transition in disordered
nanodiamond arrays as a function of the dispersion of intergrain spacing,
which ranges from angstroms to micrometers. By monitoring the evolved
superconducting gaps and diminished coherence peaks in the single-quasiparticle
density of states, we link the destruction of the superconducting
state and the emergence of bosonic dirty metallic state to breaking
of the global phase coherence and persistence of the localized Cooper
pairs. The observed resistive bosonic phase transitions are well modeled
using a series–parallel circuit in the framework of bosonic
confinement and coherence
Superconducting Ferromagnetic Nanodiamond
Superconductivity and ferromagnetism
are two mutually antagonistic
states in condensed matter. Research on the interplay between these
two competing orderings sheds light not only on the cause of various
quantum phenomena in strongly correlated systems but also on the general
mechanism of superconductivity. Here we report on the observation
of the electronic entanglement between superconducting and ferromagnetic
states in hydrogenated boron-doped nanodiamond films, which have a
superconducting transition temperature <i>T</i><sub>c</sub> ∼ 3 K and a Curie temperature <i>T</i><sub>Curie</sub> > 400 K. In spite of the high <i>T</i><sub>Curie</sub>, our nanodiamond films demonstrate a decrease in the temperature
dependence of magnetization below 100 K, in correspondence to an increase
in the temperature dependence of resistivity. These anomalous magnetic
and electrical transport properties reveal the presence of an intriguing
precursor phase, in which spin fluctuations intervene as a result
of the interplay between the two antagonistic states. Furthermore,
the observations of high-temperature ferromagnetism, giant positive
magnetoresistance, and anomalous Hall effect bring attention to the
potential applications of our superconducting ferromagnetic nanodiamond
films in magnetoelectronics, spintronics, and magnetic field sensing