Layered metal diborides that contain metal atoms sandwiched between boron honeycomb planes offer a rich opportunity to access graphenic forms of boron. We recently demonstrated that magnesium diboride (MgB ) could be exfoliated by ultrasonication in water to yield boron-based nanosheets. However, knowledge of the fate of metal boride crystals in aqueous phases is still in its incipient stages. This work presents our preliminary findings on the discovery that MgB crystals can undergo dissolution in water under ambient conditions to result in precursors (prenucleation clusters) that, upon aging, undergo nonclassical crystallization preferentially growing in lateral directions by two-dimensional (2D) oriented attachment. We show that this recrystallization can be utilized as an avenue to obtain a high yield (≈92 %) of boron-based nanostructures, including nanodots, nanograins, nanoflakes, and nanosheets. These nanostructures comprise boron honeycomb planes chemically modified with hydride and oxy functional groups, which results in an overall negative charge on their surfaces. This ability of MgB crystals to yield prenucleation clusters that can self-seed to form nanostructures comprising chemically modified boron honeycomb planes presents a new facet to the physicochemical interaction of MgB with water. These findings also open newer avenues to obtain boron-based nanostructures with tunable morphologies by varying the chemical milieu during recrystallization.
Two-dimensional (2D) metal-boride-derived nanostructures have been a focus of intense research for the past decade, with an emphasis on new synthetic approaches, as well as on the exploration of possible applications in next-generation advanced materials and devices. Their unusual mechanical, electronic, optical, and chemical properties, arising from low dimensionality, present a new paradigm to the science of metal borides that has traditionally focused on their bulk properties. This Perspective discusses the current state of research on metalboride-derived 2D nanostructures, highlights challenges that must be overcome, and identifies future opportunities to fully utilize their potential.
Metal
borides have attracted the attention of researchers due to
their useful physical properties and unique ability to form high hydrogen-capacity
metal borohydrides. We demonstrate improved hydrogen storage properties
of a nanoscale Mg–B material made by surfactant ball milling
MgB2 in a mixture of heptane, oleic acid, and oleylamine.
Transmission electron microscopy data show that Mg–B nanoplatelets
are produced with sizes ranging from 5 to 50 nm, which agglomerate
upon ethanol washing to produce an agglomerated nanoscale Mg–B
material of micron-sized particles with some surfactant still remaining.
X-ray diffraction measurements reveal a two-component material where
32% of the solid is a strained crystalline solid maintaining the hexagonal
structure with the remainder being amorphous. Fourier transform infrared
shows that the oleate binds in a “bridge-bonding” fashion
preferentially to magnesium rather than boron, which is confirmed
by density functional theory calculations. The Mg–B nanoscale
material is deficient in boron relative to bulk MgB2 with
a Mg–B ratio of ∼1:0.75. The nanoscale MgB0.75 material has a disrupted B–B ring network as indicated by
X-ray absorption measurements. Hydrogenation experiments at 700 bar
and 280 °C show that it partially hydrogenates at temperatures
100 °C below the threshold for bulk MgB2 hydrogenation.
In addition, upon heating to 200 °C, the H–H bond-breaking
ability increases ∼10-fold according to hydrogen–deuterium
exchange experiments due to desorption of oleate at the surface. This
behavior would make the nanoscale Mg–B material useful as an
additive where rapid H–H bond breaking is needed.
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