Metal-assisted catalytic etching (MACE) involving Ag deposited on Si particles has been reported as a facile method for the production of Si nanowires (Si NWs). We show that the structure of Si particles subjected to MACE changes dramatically in response to changing the loading of the Ag catalyst. The
Metal-assisted catalytic etching (MACE) using Ag nanoparticles as catalysts and H2O2 as oxidant has been performed on single-crystal Si wafers, single-crystal electronics grade Si powders, and polycrystalline metallurgical grade Si powders. The temperature dependence of the etch kinetics has been measured over the range 5–37°C. Etching is found to proceed preferentially in a 〈001〉 direction with an activation energy of ~0.4 eV on substrates with (001), (110), and (111) orientations. A quantitative model to explain the preference for etching in the 〈001〉 direction is developed and found to be consistent with the measured activation energies. Etching of metallurgical grade powders produces particles, the surfaces of which are covered primarily with porous silicon (por-Si) in the form of interconnected ridges. Silicon nanowires (SiNW) and bundles of SiNW can be harvested from these porous particles by ultrasonic agitation. Analysis of the forces acting between the metal nanoparticle catalyst and the Si particle demonstrates that strongly attractive electrostatic and van der Waals interactions ensure that the metal nanoparticles remain in intimate contact with the Si particles throughout the etch process. These attractive forces draw the catalyst toward the interior of the particle and explain why the powder particles are etched equivalently on all the exposed faces.
The recently discovered low-load
metal-assisted catalytic etching
(LL-MACE) creates nanostructured Si with controllable and variable
characteristics that distinguish this technique from the conventional
high-load variant. LL-MACE employs 150 times less metal catalyst and
produces porous Si instead of Si nanowires. In this work, we demonstrate
that some of the features of LL-MACE cannot be explained by the present
understanding of MACE. With mechanistic insight derived from extensive
experimentation, it is demonstrated that (1) the method allows the
use of not only Ag, Pd, Pt, and Au as metal catalysts but also Cu
and (2) judicious combinations of process parameters such as the type
of metal, Si doping levels, and etching temperatures facilitate control
over yield (0.065–88%), pore size (3–100 nm), specific
surface area (20–310 m2·g–1), and specific pore volume (0.05–1.05 cm3·g–1). The porous structure of the product depends on
the space-charge layer, which is controlled by the Si doping and the
chemical identity of the deposited metal. The porous structure was
also dependent on the dynamic structure of the deposited metal. A
distinctive comet-like structure of metal nanoparticles was observed
after etching with Cu, Ag, Pd, and, in some cases, Pt; this structure
consisted of 10–50 nm main particles surrounded by smaller
(<5 nm) nanoparticles. With good scalability and precise control
of structural properties, LL-MACE facilitates Si applications in photovoltaics,
energy storage, biomedicine, and water purification.
Two dimensional electron gases (2DEGs) formed at the interfaces of oxide heterostructures draw considerable interest owing to their unique physics and potential applications. Growing such heterostructures on conventional semiconductors has the potential to integrate their functionality with semiconductor device technology. We demonstrate 2DEGs on a conventional semiconductor by growing GdTiO 3 -SrTiO 3 on silicon. Structural analysis confirms the epitaxial growth of heterostructures with abrupt interfaces and a high degree of crystallinity. Transport measurements show the conduction to be an interface effect, with ~9×10 13 cm -2 electrons per interface. Good agreement is demonstrated between the electronic behavior of structures grown on Si and on an oxide substrate, validating the robustness of this approach to bridge between lab-scale samples to a scalable, technologically relevant materials system.
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