Heat smarter, not harder: How microwaves make catalytic reactions more efficient

Date:
July 27, 2020
Source:
Tokyo Institute of Technology
Summary:
Scientists demonstrate a synchrotron X-ray spectroscopy-based
method by which the local temperatures of metal nanoparticles can be
measured under microwaves. This approach provides insight into the
role that their temperature has on their catalytic performance and
sheds light on how local particle heating using microwaves could
become a critical strategy for improving the energy efficiency of
catalytic reactions.



FULL STORY ==========================================================================
Many reactions that we use to produce chemical compounds in food,
medical, and industrial fields would not be feasible without the use of catalysts. A catalyst is a substance that, even in small quantities, accelerates the rate of a chemical reaction and sometimes allows it
to occur at milder conditions (lower temperature and pressure). A good
catalyst can sometimes multiply the throughput of an industrial-scale
reactor or shave more than 100DEGC off of its operating temperature.


==========================================================================
It is no surprise, then, that catalyst research is crucial for making
chemical reactions more efficient. One emerging approach that has been
observed to provide these benefits is heating the metal nanoparticles in
some catalysts directly using microwaves instead of conventional uniform heating techniques.

Metal nanoparticles in catalysts interact strongly with microwaves and
are believed to be heated selectively. However, scientists have reported conflicting results when using this approach, and understanding the effect
that selectively heating the nanoparticles has on chemical reactions is difficult because no methods for measuring their local temperature have
been found yet.

Now, scientists at Tokyo Tech led by Prof Yuji Wada tackle this problem
and demonstrate a novel approach for measuring the local temperature of platinum nanoparticles in a solid catalyst. Their method, as detailed
in their study published in Communications Chemistry, relies on X-ray absorption fine structure (XAFS) spectroscopy, which, as the name implies, provides information on the small local structures of a material using
X-rays.

In extended XAFS oscillations, a value called the Debye-Waller factor
can be derived. This factor is comprised of two terms; one related
to structural disorder, and one related to thermal disorder. If the
structure of the catalyst does not change upon microwave heating,
any variation in the Debye-Waller factor has to be due to thermal
variations. Therefore, XAFS can be used to indirectly measure the
temperature of metal nanoparticles.

The team of scientists tested this approach in "platinum on alumina" and "platinum on silica" catalysts to find out to what extent microwaves can selectively heat the platinum nanoparticles instead of their supporting material. Microwave heating was found to produce a marked temperature difference between NP and support. A series of comparative experiments demonstrated that a higher local temperature of the metal nanoparticles
in catalysts is crucial to obtaining higher reaction rates at the same temperature.

Excited about the results, Prof Wada remarks: "This work is the first
to present a method for the assessment of the local temperatures of nanoparticles and their effect on catalytic reactions. We conclude that
the local heating of platinum nanoparticles is efficient for accelerating chemical reactions that involve platinum itself, presenting a practical approach to obtain a dramatic enhancement in catalytic reactions using microwave heating." These findings represent a breakthrough for improving
our understanding of the role of microwave heating in enhancing catalytic performance. Dr. Tsubaki adds, "Efficient energy concentration at the
active sites of catalysts -- the metal nanoparticles in this case --
should become a critical strategy for exploring microwave chemistry
to achieve efficient energy use for reactions and to enable milder
conditions for reaction acceleration." This new insight into catalytic processes will hopefully save tons of energy in the long run by making
reactors work smarter, not harder.


========================================================================== Story Source: Materials provided by Tokyo_Institute_of_Technology. Note: Content may be edited for style and length.


========================================================================== Journal Reference:
1. Taishi Ano, Shuntaro Tsubaki, Anyue Liu, Masayuki Matsuhisa, Satoshi
Fujii, Ken Motokura, Wang-Jae Chun, Yuji Wada. Probing the
temperature of supported platinum nanoparticles under microwave
irradiation by in situ and operando XAFS. Communications Chemistry,
2020; 3 (1) DOI: 10.1038/ s42004-020-0333-y ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2020/07/200727114714.htm

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