Size-Dependent Activity of Iron Nanoparticles in Both Thermal and Plasma Driven Catalytic Ammonia Decomposition

Chen, Genwei; Qu, Jing; Cheah, Pohlee; Cao, Dongmei; Zhao, Yongfeng; Xiang, Yizhi

doi:10.1021/acs.iecr.2c02092

Cited by 9 publications

(22 citation statements)

References 45 publications

(89 reference statements)

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“…The reactor system has been shown in our previous report, although the specific reactor parameters are different. 48 Specifically, a 6 cm long stainless steel mesh (20 mesh) was employed as the outer electrode and wrapped tight around the quartz tube. The out electrode was wrapped with ceramic fiber for insulation.…”

Section: Methodsmentioning

confidence: 99%

“…The DBD plasma-assisted carbonization was performed in a coaxial DBD reactor consisting of a quartz tube with an inner diameter of 7 mm and an outer diameter of 3/8″. The reactor system has been shown in our previous report, although the specific reactor parameters are different . Specifically, a 6 cm long stainless steel mesh (20 mesh) was employed as the outer electrode and wrapped tight around the quartz tube.…”

Section: Methodsmentioning

confidence: 99%

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Accelerated Synthesis of Ordered Mesoporous Carbons Using Plasma

et al. 2023

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Conventional ordered mesoporous carbon (OMC) production usually requires long processing times in the carbonization step to achieve desired temperatures through controlled ramps. To enable expedited materials discovery, developing advanced manufacturing capability with significantly improved throughput is highly desired. Current approaches for accelerating the synthesis of OMCs include using microwave and Joule heating. However, both methods rely on the introduction of additional components, such as microwave absorbers and electrically conductive agents, within the bulk materials to impart the ability to reach high carbonization temperatures. This work demonstrates accelerated synthesis and functionalization of OMCs through the use of a dielectric barrier discharge plasma, where carbonization can be accomplished within 15 min using 30 W plasma sources, representing more than an order of magnitude increase in polymer-to-carbon conversion kinetics compared to that of a traditionally pyrolyzed analogue. Particularly, the ability of performing rapid carbonization without the use of additional substrates within the OMC precursor systems is advantageous. A systematic investigation of how plasma power, time, and gas atmosphere impact the resulting OMC pore textures and properties is performed, demonstrating the broad applicability of plasma-enabled carbonization methods. Furthermore, we demonstrate that the plasma treatment strategy can be extended to incorporate heteroatoms into the carbon framework by introducing ammonia gas, resulting in OMCs with a nitrogen content up to 4.7 at %, as well as non-Pluronic templating systems for synthesizing OMC with pore sizes larger than 10 nm. As employing a plasma source for materials pyrolysis is an industrially relevant approach, our system can be extended toward scaled synthesis of OMCs with much faster production rates.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Accelerated Synthesis of Ordered Mesoporous Carbons Using Plasma

et al. 2023

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“…Similarly, particle size dependence on ammonia conversion and energy efficiency over unmodified alumina support material has also been reported by El-Shafie et al 185 Although more description about the nature of alumina used was not reported in this study, the authors observed that increasing the alumina particle size from 1 to 2 mm led to a decrease in NH 3 conversion from 83.19% to 80.35%, with a corresponding decrease in energy efficiency. 185 Chen et al 186 studied the particle size dependence of Fe on the NH 3 conversion with a particle size range of 4.2−10.4 nm. Different Fe 2 O 3 nanoparticles were prepared using the polyol method and dispersed on the Al 2 O 3 using impregnation techniques.…”

Section: Advancements and Currentmentioning

confidence: 99%

Plasma Catalysis for Hydrogen Production: A Bright Future for Decarbonization

Wang,

Otor,

Rivera-Castro

et al. 2024

ACS Catal.

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Thermal approaches have played a dominant role in driving chemical reactions within the chemicals and fuels industries, benefiting from ongoing enhancements in efficiency via heat integration, catalyst development, and process intensification. Nevertheless, these traditional thermal approaches remain heavily reliant on fossil fuels, and there exists an urgent demand for the implementation of renewable energy technologies to synthesize fuels, commodity chemicals, and specialty chemicals. Nonthermal plasmas have gained considerable attention in recent years as a promising solution, and the prospects of combining plasmas with suitable catalysts have become even more appealing. Moreover, the evolution of nonthermal plasma catalysis approaches for the generation of clean hydrogen could be transformative in reducing greenhouse gas emissions. This comprehensive review highlights the influential contributions in plasma catalysis for hydrogen production, discusses recent advancements, and provides future prospects for researchers aiming to advance the production of clean hydrogen.

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“…DBD reactor together with Fe 3 O 4 catalysts was also studied by Chen et al in 2022, who showed that the activity increased with increasing particle size. 102 2.3. Electrolysis for Ammonia Cracking.…”

Section: Catalysts Combining Plasmamentioning

confidence: 99%

“…They concluded that the SiO 2 material can be utilized as a catalyst, in view of enabling lower costs compared to Ru materials. DBD reactor together with Fe 3 O 4 catalysts was also studied by Chen et al in 2022, who showed that the activity increased with increasing particle size …”

Section: Ammonia Decomposition Technologiesmentioning

confidence: 99%

Ammonia as a Carbon-Free Energy Carrier: NH₃ Cracking to H₂

Spatolisano

Pellegrini

Angelis

et al. 2023

Ind. Eng. Chem. Res.

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In the energy transition from fossil fuels to renewables, hydrogen is a realistic alternative to achieving the decarbonization target. However, its chemical and physical properties make its storage and transport expensive. To ensure the cost-effective H 2 usage as an energy vector, other chemicals are getting attention as H 2 carriers. Among them, ammonia is the most promising candidate. The value chain of NH 3 as a H 2 carrier, considering the long-distance ship transport, includes NH 3 synthesis and storage at the loading terminal, NH 3 storage at the unloading terminal, and its cracking to release H 2 . NH 3 synthesis and cracking are the cost drivers of the value chain. Also, the NH 3 cracking at large scale is not a mature technology, and a significant effort has to be made in intensifying the process as much as possible. In this respect, this work reviews the available technologies for NH 3 cracking, critically analyzing them in view of the scale up to the industrial level.

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Size-Dependent Activity of Iron Nanoparticles in Both Thermal and Plasma Driven Catalytic Ammonia Decomposition

Cited by 9 publications

References 45 publications

Accelerated Synthesis of Ordered Mesoporous Carbons Using Plasma

Accelerated Synthesis of Ordered Mesoporous Carbons Using Plasma

Plasma Catalysis for Hydrogen Production: A Bright Future for Decarbonization

Ammonia as a Carbon-Free Energy Carrier: NH₃ Cracking to H₂

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Size-Dependent Activity of Iron Nanoparticles in Both Thermal and Plasma Driven Catalytic Ammonia Decomposition

Cited by 9 publications

References 45 publications

Accelerated Synthesis of Ordered Mesoporous Carbons Using Plasma

Accelerated Synthesis of Ordered Mesoporous Carbons Using Plasma

Plasma Catalysis for Hydrogen Production: A Bright Future for Decarbonization

Ammonia as a Carbon-Free Energy Carrier: NH3 Cracking to H2

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Product

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Ammonia as a Carbon-Free Energy Carrier: NH₃ Cracking to H₂