Matthew Prosniewski scite author profile

Matthew Prosniewski

5Publications

50Citation Statements Received

77Citation Statements Given

How they've been cited

How they cite others

183

Affiliations

University of Missouri

Publications

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Boron-neutron Capture on Activated Carbon for Hydrogen Storage

Romanos

Beckner

Prosniewski

et al. 2019

Sci Rep

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This work investigates the effects of neutron irradiation on nitrogen and hydrogen adsorption in boron-doped activated carbon. Boron-neutron capture generates an energetic lithium nucleus, helium nucleus, and gamma photons, which can alter the surface and structure of pores in activated carbon. The defects introduced by fission tracks are modeled assuming the slit-shaped pores geometry. Sub-critical nitrogen adsorption shows that nitrogen molecules cannot probe the defects created by fission tracks. Hydrogen adsorption isotherms of irradiated samples indicate higher binding energies compared to their non-irradiated parent samples.

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Cycling and Regeneration of Adsorbed Natural Gas in Microporous Materials

et al. 2017

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Adsorbed natural gas (ANG) technology is an energy-efficient method for storing natural gas at room temperature and low pressure. The search for high-storage-performance natural gas sorbents for gaseous fuels is currently pursued by numerous research groups worldwide. While research in this field is mainly devoted to optimizing the gravimetric and volumetric storage capacity of methane, this work investigates the long-term effect of large alkanes on natural gas storage. This article investigates the evolution of storage capacity and gas composition during adsorption/desorption cycles at room temperature (charge/discharge of an ANG tank) and at various elevated temperatures (regeneration of tank) on a commercial, high-surface-area activated carbon (Maxsorb MSC-30, Kansai Coke and Chemical Co. Ltd.). Cycling and regeneration study of sorbent for hundreds of cycles has been investigated. The evolution of storage capacity is measured after successive cycling using a custom-built Sievert apparatus. For natural gas, gravimetric excess adsorption drops to 33% in the first 100 cycles and continues to decrease slowly until it reaches 25% by the 1000th cycle. Volumetric storage capacity shows a deterioration of 50% after 100 cycles and remains approximately constant after that. The contaminant gas composition is measured as a function of successive cycling using gas chromatography. Finally, efficient regeneration techniques have been tested to allow a continuous operation for thousands of cycles.

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Evaluating methane adsorbed film densities on activated carbon in dynamic systems

Prosniewski¹,

Gillespie²,

Knight³

et al. 2018

Journal of Energy Storage

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Determination of the enthalpy of adsorption of hydrogen in activated carbon at room temperature

Knight

Gillespie

Prosniewski

et al. 2020

International Journal of Hydrogen Energy

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Effect of cycling and thermal control on the storage and dynamics of a 40-L monolithic adsorbed natural gas tank

Prosniewski

Rash

Romanos

et al. 2019

Fuel

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