8 research outputs found
Influence of Cetyltrimethylammonium Bromide on Gold Nanocrystal Formation Studied by In Situ Liquid Cell Scanning Transmission Electron Microscopy
The
synthesis of monodisperse size- and shape-controlled Au nanocrystals
is often achieved with cetyltrimethylammonium bromide (CTAB) surfactant;
however, its role in the growth of such tailored nanostructures is
not well understood. To elucidate the formation mechanism(s) and evolution
of the morphology of Au nanocrystals in the early growth stage, we
present an in situ liquid-cell scanning transmission electron microscopy
(STEM) investigation using electron beam-induced radiolytic species
as the reductant. The resulting particle shape at a low beam dose
rate is shown to be strongly influenced by the surfactant; the Au
nanocrystal growth rate is suppressed by increasing the CTAB concentration.
At a low CTAB concentration, the nanoparticles (NPs) follow a reaction-limited
growth mechanism, while at high a CTAB concentration the NPs follow
a diffusion-limited mechanism, as described by the Lifshitz–Slyozov–Wagner
(LSW) model. Moreover, we investigate the temporal evolution of specific
NP geometries. The amount of Au reduced by the electron beam outside
the irradiated area is quantified to better interpret the nanocrystal
growth kinetics, as well as to further develop an understanding of
electron beam interactions with nanomaterials toward improving the
interpretation of in situ measurements
Spiny Rhombic Dodecahedral CuPt Nanoframes with Enhanced Catalytic Performance Synthesized from Cu Nanocube Templates
Platinum
was coated on the surfaces of copper nanocubes to form
Cu–CuPt core–alloy–frame nanocrystals with a
rhombic dodecahedral (RD) shape. Co-reduction of Pt<sup>2+</sup> ions
and residual Cu<sup>+</sup> ions in the supernatant of the Cu nanocube
solution followed by the interdiffusion of Cu and Pt atoms over the
core–shell interface allowed their formation. Growth in the
⟨100⟩ directions of the {100}-terminated Cu nanocubes
resulted in the {110}-faceted rhombic dodecahedra. By the introduction
of additional Pt precursor, the {100} vertices of the Cu–CuPt
RD nanocrystals could be selectively extended to form spiny CuPt RD
nanocrystals. After removing the Cu core template, both CuPt alloy
RD and spiny CuPt alloy RD nanoframes (NFs) were obtained with Pt/Cu
ratios of 26/74 and 41/59, respectively. Abundant surface defects
render them highly active catalysts due to the open frame structure
of both sets of NFs. The spiny RD NFs showed superior specific activity
toward the oxygen reduction reaction, 1.3 and 3 times to those of
the RD NFs and the commercial Pt/C catalysts, respectively. In 4-nitrophenol
reduction, both NFs displayed better activity compared to commercial
Pt NPs in the dark. Their activities were improved ∼1.3 times
under irradiation of visible light, attributed to the effect of LSPR
enhancement by the Cu-rich skeleton
Turning the Halide Switch in the Synthesis of Au–Pd Alloy and Core–Shell Nanoicosahedra with Terraced Shells: Performance in Electrochemical and Plasmon-Enhanced Catalysis
Au–Pd
nanocrystals are an intriguing system to study the integrated functions
of localized surface plasmon resonance (LSPR) and heterogeneous catalysis.
Gold is both durable and can harness incident light energy to enhance
the catalytic activity of another metal, such as Pd, via the SPR effect
in bimetallic nanocrystals. Despite the superior catalytic performance
of icosahedral (IH) nanocrystals compared to alternate morphologies,
the controlled synthesis of alloy and core–shell IH is still
greatly challenged by the disparate reduction rates of metal precursors
and lack of continuous epigrowth on multiply twinned boundaries of
such surfaces. Herein, we demonstrate a one-step strategy for the
controlled growth of monodisperse Au–Pd alloy and core–shell
IH with terraced shells by turning an ionic switch between [Br<sup>–</sup>]/[Cl<sup>–</sup>] in the coreduction process.
The core–shell IH nanocrystals contain AuPd alloy cores and
ultrathin Pd shells (<2 nm). They not only display more than double
the activity of the commercial Pd catalysts in ethanol electrooxidation
attributed to monatomic step terraces but also show SPR-enhanced conversion
of 4-nitrophenol. This strategy holds promise toward the development
of alternate bimetallic IH nanocrystals for electrochemical and plasmon-enhanced
catalysis
Shaped Pd–Ni–Pt Core-Sandwich-Shell Nanoparticles: Influence of Ni Sandwich Layers on Catalytic Electrooxidations
Shape-controlled metal nanoparticles (NPs) interfacing Pt and nonprecious metals (M) are highly active energy conversion electrocatalysts; however, there are still few routes to shaped M–Pt core–shell NPs and fewer studies on the geometric effects of shape and strain on catalysis by such structures. Here, well-defined cubic multilayered Pd–Ni–Pt sandwich NPs are synthesized as a model platform to study the effects of the nonprecious metal below the shaped Pt surface. The combination of shaped Pd substrates and mild reduction conditions directs the Ni and Pt overgrowth in an oriented, layer-by-layer fashion. Exposing a majority of Pt(100) facets, the catalytic performance in formic acid and methanol electro-oxidations (FOR and MOR) is assessed for two different Ni layer thicknesses and two different particle sizes of the ternary sandwich NPs. The strain imparted to the Pt shell layer by the introduction of the Ni sandwich layer (Ni–Pt lattice mismatch of ∼11%) results in higher specific initial activities compared to core–shell Pd–Pt bimetallic NPs in alkaline MOR. The trends in activity are the same for FOR and MOR electrocatalysis in acidic electrolyte. However, restructuring in acidic conditions suggests a more complex catalytic behavior from changes in composition. Notably, we also show that cubic quaternary Au–Pd–Ni–Pt multishelled NPs, and Pd–Ni–Pt nanooctahedra can be generated by the method, the latter of which hold promise as potentially highly active oxygen reduction catalysts
Formation of the Conducting Filament in TaO<sub><i>x</i></sub>‑Resistive Switching Devices by Thermal-Gradient-Induced Cation Accumulation
The distribution of tantalum and
oxygen ions in electroformed and/or switched TaO<sub><i>x</i></sub>-based resistive switching devices has been assessed by high-angle
annular dark-field microscopy, X-ray energy-dispersive spectroscopy,
and electron energy-loss spectroscopy. The experiments have been performed
in the plan-view geometry on the cross-bar devices producing elemental
distribution maps in the direction perpendicular to the electric field.
The maps revealed an accumulation of +20% Ta in the inner part of
the filament with a 3.5% Ta-depleted ring around it. The diameter
of the entire structure was approximately 100 nm. The distribution
of oxygen was uniform with changes, if any, below the detection limit
of 5%. We interpret the elemental segregation as due to diffusion
driven by the temperature gradient, which in turn is induced by the
spontaneous current constriction associated with the negative differential
resistance-type <i>I</i>–<i>V</i> characteristics
of the as-fabricated metal/oxide/metal structures. A finite-element
model was used to evaluate the distribution of temperature in the
devices and correlated with the elemental maps. In addition, a fine-scale
(∼5 nm) intensity contrast was observed within the filament
and interpreted as due phase separation of the functional oxide in
the two-phase composition region. Understanding the temperature-gradient-induced
phenomena is central to the engineering of oxide memory cells
3D Analysis of Fuel Cell Electrocatalyst Degradation on Alternate Carbon Supports
Understanding
the mechanisms associated with Pt/C electrocatalyst degradation in
proton exchange membrane fuel cell (PEMFC) cathodes is critical for
the future development of higher-performing materials; however, there
is a lack of information regarding Pt coarsening under PEMFC operating
conditions within the cathode catalyst layer. We report a direct and
quantitative 3D study of Pt dispersions on carbon supports (high surface
area carbon (HSAC), Vulcan XC-72, and graphitized carbon) with varied
surface areas, graphitic character, and Pt loadings ranging from 5
to 40 wt %. This is accomplished both before and after catalyst-cycling
accelerated stress tests (ASTs) through observations of the cathode
catalyst layer of membrane electrode assemblies. Electron tomography
results show Pt nanoparticle agglomeration occurs predominantly at
junctions and edges of aggregated graphitized carbon particles, leading
to poor Pt dispersion in the as-prepared catalysts and increased coalescence
during ASTs. Tomographic reconstructions of Pt/HSAC show much better
initial Pt dispersions, less agglomeration, and less coarsening during
ASTs in the cathode. However, a large loss of the electrochemically
active surface area (ECSA) is still observed and is attributed to
accelerated Pt dissolution and nanoparticle coalescence. Furthermore,
a strong correlation between Pt particle/agglomerate size and measured
ECSA is established and is proposed as a more useful metric than average
crystallite size in predicting degradation behavior across different
catalyst systems
Aqueous Synthesis of Concave Rh Nanotetrahedra with Defect-Rich Surfaces: Insights into Growth‑, Defect‑, and Plasmon-Enhanced Catalytic Energy Conversion
The control of morphology in the
synthesis of Rh nanocrystals can
be used to precisely tailor the electronic surface structure; this
in turn directly influences their performance in catalysis applications.
Many works have brought attention to the development of Rh nanostructures
with low-index surfaces, but limited effort has been devoted to the
study of high-index and surface defect-enriched nanocrystals as they
are not favored by thermodynamics because of the involvement of high-energy
surfaces and increased surface-to-volume ratios. In this work, we
demonstrate an aqueous synthesis of concave Rh nanotetrahedra (CTDs)
serving as efficient catalysts for energy conversion reactions. CTDs
are surface defect-rich structures that form through a slow growth
rate and follow the four-step model of metallic nanoparticle growth.
Via the tuning of the surfactant concentration, the morphology of
Rh CTDs evolved into highly excavated nanotetrahedra (HETDs) and twinned
nanoparticles (TWs). Unlike the CTD surfaces with abundant adatoms
and vacancies, HETDs and TWs have more regular surfaces with layered
terraces. Each nanocrystal type was evaluated for methanol electrooxidation
and hydrogen evolution from hydrolysis of ammonia borane, and the
CTDs significantly showed the best catalytic performance because of
defect enrichment, which benefits the surface reactivity of adsorbates.
In addition, both CTDs and HETDs have strong absorption near the visible
light region (382 and 396 nm), for which they show plasmon-enhanced
performance in photocatalytic hydrogen evolution under visible light
illumination. CTDs are more photoactive than HETDs, likely because
of more pronounced localized surface plasmon resonance hot spots.
This facile aqueous synthesis of large-surface-area, defect-rich Rh
nanotetrahedra is exciting for the fields of nanosynthesis and catalysis
Control of Architecture in Rhombic Dodecahedral Pt–Ni Nanoframe Electrocatalysts
Platinum-based
alloys are known to demonstrate advanced properties
in electrochemical reactions that are relevant for proton exchange
membrane fuel cells and electrolyzers. Further development of Pt alloy
electrocatalysts relies on the design of architectures with highly
active surfaces and optimized utilization of the expensive element,
Pt. Here, we show that the three-dimensional Pt anisotropy of Pt–Ni
rhombic dodecahedra can be tuned by controlling the ratio between
Pt and Ni precursors such that either a completely hollow nanoframe
or a new architecture, the excavated nanoframe, can be obtained. The
excavated nanoframe showed ∼10 times higher specific and ∼6
times higher mass activity for the oxygen reduction reaction than
Pt/C, and twice the mass activity of the hollow nanoframe. The high
activity is attributed to enhanced Ni content in the near-surface
region and the extended two-dimensional sheet structure within the
nanoframe that minimizes the number of buried Pt sites