Nano-objects
are favored structures for applications such as catalysis
and sensing. Although they already provide a large surface-to-volume
ratio, this ratio can be further increased by shape-selective plating
of the nanostructure surfaces. This process combines the conformity
of autocatalytic deposition with the defined nucleation and growth
characteristics of colloidal nanoparticle syntheses. However, many
aspects of such reactions are still not fully understood. In this
study, we investigate in detail the growth of spiky nickel nanotubes
in polycarbonate template membranes. One distinctive feature of our
synthesis is the simultaneous growth of nanospikes on both the inside
and outside of nanotubes while the tubes are still embedded in the
polymer. This is achieved by combining the plating process with locally
enhanced in situ etching of the poylmer template, for which we propose
a theory. Electron microscopy investigations reveal twinning defects
as the driving force for the growth of crystalline nanospikes. Deposit
crystallinity is ensured by the reducing agent hydrazine. Iminodiacetic
acid is not only used as a complexing agent during synthesis but apparently
also acts as a capping agent and limits random nucleation on the spike
facets. Finally, we apply our synthesis to templates with interconnected
pores to obtain free-standing spiky nickel nanotube networks, demonstrating
its ability to homogeneously coat substrates with extended inner surfaces
and to operate in nanoscale confinement.
Due to its simplicity, flexibility and conformity, electroless plating presents itself as an attractive route towards functional metal nanostructures. Despite the importance for creating multimetallic materials with enhanced properties, the complex interactions between the components in electroless plating baths make alloy formations a challenging objective. In this work, we outline an electroless plating strategy fabricating Pd−Pt alloy nanomaterials, which is based on arbitrarily miscible plating baths for the individual metals. To demonstrate the excellent nanoscale conformity and homogeneity of our plating system, we apply it to ion track‐etched polymer templates with large inner surfaces as ambitious substrates, resulting in the formation of 3D free‐standing PdxPt100‐x‐nanotube‐networks (NTNWs). Based on the electro‐oxidation of methanol as a model reaction, we utilize the compositional freedom provided by our syntheses for optimizing the catalytic performance of our metal NTNWs, which heavily depends on the Pd−Pt ratio. Within our system, the highest surface normalized activity was found for the Pd20Pt80 NTNW, reaching more than a two‐fold increase of the peak current density in comparison to pure Pt. Overall, our reaction system provides a versatile toolkit for fabricating intricate Pd−Pt nanostructures of arbitrary elemental composition, and constitutes a starting point for designing new electroless alloy plating baths.
Autocatalytic deposition represents a facile, versatile, and scalable wet‐chemical tool for nanofabrication. However, the intricate component interplay in plating baths containing multiple metal species impedes alloy deposition. We resolved this challenge in the bimetallic copper‐platinum system by exploiting the kinetic stability of platinum complexes, which allows adjusting their ligand sphere and thus reactivity independently from the present copper ions in a preceding, thermally activated ligand exchange step. By using metastable PtIV precursors of varying degrees of complexation, copper‐platinum alloys of adjustable atomic ratio were plated from solutions of identical composition and concentration, but differing local coordination environment. Due to its excellent conformity and nanoscale homogeneity, the reaction is compatible with ambitious 3D substrate morphologies, as demonstrated in the template‐assisted fabrication of nanotubes with high aspect ratio. The ability to generate additional synthetic degrees of freedom by decoupling the metal complex speciation from the solution composition is of large interest for redox‐chemical synthesis techniques, such as electrodeposition or nanoparticle colloid production.
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