Abstract
This review article focuses on the latest advances in the synthesis of inorganic nano-catalysts using microwave heating, which has progressed significantly since its initial implementation in the mid-1980s. Over the years, nanoparticles (NPs), which inherently offer better surface accessibility for heterogeneous catalysis, have been synthesized using a wide array of heating methods. Microwave heating is one such method and employs a unique heating mechanism that can have several benefits for catalysis. When compared to conventional form of heating which relies on inter-layer mixing via convection, microwave heating operates through the chemical polarity in the target chemicals leading to an “inside-out” mode of heating. This heating mechanism is more targeted and therefore results in rapid synthesis of catalytically active NPs. Platinum group metals (PGM) have classically been the focus of nano-catalysis; however, recent efforts have also applied non-PGM group metals with the goals of lower costs, and ideally, improved catalytic reactivity and durability. This is especially of interest with respect to Pd because of its current historically high cost. Investigations into these new materials have primarily focused on new/improved synthetic methods and catalytic compositions, but it is important to note that these approaches must also be economic and scalable to attain practical relevance. With this overarching goal in mind, this review summarizes notable recent findings with a focus on Pd-dilution and microwave heating in a chronological fashion.
Highlights
Microwave heating for material synthesis has advanced significantly since its initial application in the mid-1980s
This study showed the versatility of μwH during the synthesis of Pd@Pt/rGO NPs and during three distinct types of catalytic reactions
Application of μwH has come a long way since its first implementation in 1984
Summary
Microwave heating (μwH) for material synthesis has advanced significantly since its initial application in the mid-1980s. As an alternative heating mode that allows high throughput syntheses, μwH offers several distinct advantages that can be divided into three key points. The rapid heating associated with μwH can result in “hot-spots,” and with proper control, this can be harnessed for synthesizing materials that would otherwise be metastable. Most important, usage of μwH can increase the overall synthesis throughput, leading to a much higher research efficiency. ΜwH usage in chemical synthesis has been increasingly explored (Figure 1) and has been the main source for some interesting. Using the keyword: “microwave synthesis nano” on 07/17/2020; statistics for 2020 was not included
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