A transparent Pyrex μ-reactor for combined <i>in situ</i> optical characterization and photocatalytic reactivity measurements

Recent advances in photocatalytic water splitting in particulate semiconductor systems have been tremendous in terms of efficiency and scalable photoreactor design. In general, photocatalyst powders are immersed in liquid water, leading to higher efficiency than gas-fed water splitting systems. Conducting a gas-phase photocatalytic reaction under water vapor, however, has several advantages versus liquid water, such as easy scalability and suppression of leaching of the catalyst components. Here, we offer a historical overview of photocatalytic water splitting under vapor feeding. Moreover, the principles of water adsorption are reviewed to understand the basic phenomena occurring on the surface of semiconductor powders. The critical role of relative humidity is identified, including water on the surface for ion conductivity, which can close the electric circuit between cathodic and anodic reaction sites. Finally, on the basis of the cross-sectional discussion of reported works in both water vapor splitting and physical property of the adsorbed water layer, how to develop the photocatalytic water vapor splitting system and the perspective of the CO2 and N2 reduction system using water vapor as an electron donor are provided.

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Section: Historical Overview Of Photocatalytic Water Vapor Splittingmentioning

confidence: 99%

Photocatalytic Hydrogen Production under Water Vapor Feeding─A Minireview

2022

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“…Despite the above mentioned numerous advantages, the traditional design of our microreactors for photocatalysis makes it necessary to seal the reactor with anodic bonding. While it is possible to perform in-situ spectroscopical analysis of the catalyst and open the reactor after reaction for post reaction characterization, the microreactor cannot be re-used after opening the lid [12]. This restriction makes the traditional microreactors single use, i.e.…”

Section: Introductionmentioning

confidence: 99%

Enabling real-time detection of photocatalytic reactions by a re-useable micro-reactor

Hochfilzer,

Aletsee,

Krempl

et al. 2023

Meas. Sci. Technol.

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We present a highly sensitive and versatile Si-based μ-reactor for photocatalytic experiments. The μ-reactor can be operated in front side (through a borosilicate window) as well as backside (through the catalyst support) illumination. The μ-reactor is sealed by compressing the Si-based microchip, a parafilm gasket and the supported catalyst by four screws. This design allows for fast and reliable assembly of the μ-reactor and the microchip is re-usable for several independent experiments, making the presented μ-reactor ideal for catalyst screening studies. We analyze volatile reactants on-line by connecting the μ-reactor to a mass-spectrometer. The limiting capillary of the μ-reactor allows for nearly 100% collection efficiency (i.e. every produced molecule will be collected) by limiting the gas flow to the mass-spectrometer—enabling highly sensitive measurements and an absolute calibration. Finally, the small height of the reactor volume results in very fast response times, which make the reactor suitable for studies of transient activity phenomena—including catalyst activation and deactivation. We demonstrate these capabilities of the μ-reactor by performing CO oxidation experiments on a TiO2 thin film with subsequent calibration of the chip. Based on a mathematical model of the μ-reactor we additionally present a method for determining the residence time, the reaction volume and the working distance.

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“…12 To date, such microreactors have rarely been applied for spectroscopic studies in heterogeneous catalysis. 11,[13][14][15][16][17] This is despite numerous advantages including good heat and mass transport properties, rapid heating/cooling, and allowing potentially higher pressures. In addition, due to the possibility to fabricate thin walls in one or two directions, they allow monitoring of reactions in situ (under controlled atmosphere) or operando (during working conditions).…”

Section: Introductionmentioning

confidence: 99%

Lithographically fabricated silicon microreactor for in situ characterization of heterogeneous catalysts—Enabling correlative characterization techniques

Baier

Rochet

Hofmann

et al. 2015

Review of Scientific Instruments

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We report on a new modular setup on a silicon-based microreactor designed for correlative spectroscopic, scattering, and analytic on-line gas investigations for in situ studies of heterogeneous catalysts. The silicon microreactor allows a combination of synchrotron radiation based techniques (e.g., X-ray diffraction and X-ray absorption spectroscopy) as well as infrared thermography and Raman spectroscopy. Catalytic performance can be determined simultaneously by on-line product analysis using mass spectrometry. We present the design of the reactor, the experimental setup, and as a first example for an in situ study, the catalytic partial oxidation of methane showing the applicability of this reactor for in situ studies.

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A transparent Pyrex μ-reactor for combined in situ optical characterization and photocatalytic reactivity measurements

Cited by 8 publications

References 19 publications

Photocatalytic Hydrogen Production under Water Vapor Feeding─A Minireview

Photocatalytic Hydrogen Production under Water Vapor Feeding─A Minireview

Enabling real-time detection of photocatalytic reactions by a re-useable micro-reactor

Lithographically fabricated silicon microreactor for in situ characterization of heterogeneous catalysts—Enabling correlative characterization techniques

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