We
report the discovery of a rule-breaking two-dimensional aluminum boride
(AlB6–ptAl–array) nanosheet with a planar
tetracoordinate aluminum (ptAl) array in a tetragonal lattice by comprehensive
crystal structure search, first-principles calculations, and molecular
dynamics simulations. It is a brand new 2D material with a unique
motif, high stability, and exotic properties. These anti-van’t
Hoff/Le Bel ptAl-arrays are arranged in a highly ordered way and connected
by two sheets of boron rhomboidal strips above and below the array.
The regular alignment and strong bonding between the constituents
of this material lead to very strong mechanical strength (in-plane
Young’s modulus Y
x
= 379, Y
y
= 437 N/m,
much larger than that of graphene, Y = 340 N/m) and high
thermal stability (the framework survived simulated annealing at 2080
K for 10 ps). Additionally, electronic structure calculations indicate
that it is a rare new material with triple Dirac
cones, Dirac-like fermions, and node-loop features. Remarkably, this
material is predicted to be a 2D phonon-mediated superconductor with T
c = 4.7 K, higher than the boiling point of
liquid helium (4.2 K). Surprisingly, the T
c can be greatly enhanced up to 30 K by applying tensile
strain at 12%. This is much higher than the temperature of
liquid hydrogen (20.3 K). These outstanding properties may pave the
way for potential applications of an AlB6–ptAl–array
in nanoelectronics and nanomechanics. This work opens up a new branch
of two-dimensional aluminum boride materials for exploration. The
present study also opens a field of two-dimensional arrays of anti-van’t
Hoff/Le Bel motifs for study.
An investigation was carried out into the cure kinetics of carbon nanofibers (CNF)/epoxy composites, composed of tetraglycidyl-4,4Ј-diaminodiphenylmethane (TGDDM) resin and 4,4Ј-diaminodiphenylsulfone (DDS) as a curing agent. The experimental data for both neat system and CNF/epoxy composites revealed an autocatalytic behavior. Analysis of DSC data indicated that the presence of carbon nanofibers had only a negligible effect on the cure kinetics of the epoxy. Kinetic analysis was performed using the phenomenological model of Kamal and two diffusion factors were introduced to describe the cure reaction in the latter stage. Activation energies and kinetic parameters were determined by fitting experimental data. Comparison between the two diffusion factors was performed, showing that the modified factor was successfully applied to the experimental data over the whole curing temperature range.
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