Novel Catalytic Systems for Hydrogen Production via the Water-Gas Shift Reaction

Petallidou, Klito C.; Polychronopoulou, Kyriaki; Efstathiou, Angelos M.

doi:10.1155/2013/426980

Cited by 2 publications

(1 citation statement)

References 37 publications

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“…In Table , we list all 32 preparation methods with the references in which these methods are utilized. − This number of preparation methods is much higher than the 12 preparation methods reported in the early database prepared by Odabaşı et al 12 preparation methods (index 1–12 in Table ) such as wet impregnation, coprecipitation, deposition precipitation, and incipient to wetness impregnation method can be found in both databases; however, 19 methods (index 13–31 in Table ) such as hydrothermal and liquid-phase reductive deposition can be found in our database only. The significant increase in preparation methods suggests a growing research focus on catalyst design innovation.…”

Section: Resultsmentioning

confidence: 99%

Preparation of a Water–Gas Shift Database to Evaluate the Performance of Noble Metal Catalysts Using Theory-Guided Machine Learning

Chattoraj,

Hamadicharef,

Syadzali

et al. 2023

ACS Catal.

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The pursuit of catalyst discovery through machine learning has garnered substantial attention in recent years. The effectiveness of such a framework in uncovering appropriate catalysts hinges greatly on the quality and quantity of data used to train the machine learning models. In this article, we report our work in curating a water−gas shift reaction database from the literature between 2013 and 2021, focusing on the usage of noble metal catalysts for fuel cell applications. Our investigation yields 8908 individual records retrieved from a total of 82 publications. The database is composed of 99 features, including 10 different base metals, 27 supports, 16 promoters, 32 preparation methods, 13 reaction conditions, and carbon monoxide conversion percentage. A machine learning approach with Shapley feature importance methodology is used to evaluate the effects of catalytic compositions and reaction conditions on carbon monoxide conversion. In our previous work, we proposed a theory-guided machine learning model, which was designed to obey the chemical reaction principles, including the thermodynamic constraint, while predicting the carbon monoxide conversion percentage. This work shows that the proposed theory-guided machine learning model outperforms other state-of-the-art machine learning models and furthermore opens up promising possibilities for finding suitable catalysts.

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Section: Resultsmentioning

confidence: 99%

Preparation of a Water–Gas Shift Database to Evaluate the Performance of Noble Metal Catalysts Using Theory-Guided Machine Learning

Chattoraj,

Hamadicharef,

Syadzali

et al. 2023

ACS Catal.

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Hydrogen Production with In Situ CO2 Capture at High and Medium Temperatures Using Solid Sorbents

et al. 2022

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Hydrogen is a versatile vector for heat and power, mobility, and stationary applications. Steam methane reforming and coal gasification have been, until now, the main technologies for H2 production, and in the shorter term may remain due to the current costs of green H2. To minimize the carbon footprint of these technologies, the capture of CO2 emitted is a priority. The in situ capture of CO2 during the reforming and gasification processes, or even during the syngas upgrade by water–gas shift (WGS) reaction, is especially profitable since it contributes to an additional production of H2. This includes biomass gasification processes, where CO2 capture can also contribute to negative emissions. In the sorption-enhanced processes, the WGS reaction and the CO2 capture occur simultaneously, the selection of suitable CO2 sorbents, i.e., with high activity and stability, being a crucial aspect for their success. This review identifies and describes the solid sorbents with more potential for in situ CO2 capture at high and medium temperatures, i.e., Ca- or alkali-based sorbents, and Mg-based sorbents, respectively. The effects of temperature, steam and pressure on sorbents’ performance and H2 production during the sorption-enhanced processes are discussed, as well as the influence of catalyst–sorbent arrangement, i.e., hybrid/mixed or sequential configuration.

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Novel Catalytic Systems for Hydrogen Production via the Water-Gas Shift Reaction

Cited by 2 publications

References 37 publications

Preparation of a Water–Gas Shift Database to Evaluate the Performance of Noble Metal Catalysts Using Theory-Guided Machine Learning

Preparation of a Water–Gas Shift Database to Evaluate the Performance of Noble Metal Catalysts Using Theory-Guided Machine Learning

Hydrogen Production with In Situ CO2 Capture at High and Medium Temperatures Using Solid Sorbents

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