Pt/graphite catalyst for hydrogen generation by HI decomposition reaction in S-I thermochemical cycle

Tyagi, Deepak; Varma, Salil; Bharadwaj, S.R.

doi:10.1002/er.3429

Cited by 13 publications

(9 citation statements)

References 43 publications

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“…O'Keefe et al reported that Pt base catalyst showed the high activity to HI decomposition (about 20.2 and 22.5% HI conversion at 673 and 773 K, respectively). Similar results were reported on Pt base catalyst by several groups . Therefore, Pt is active to the HI decomposition reaction; however, HI decomposition activity is still low under a high space velocity (SV) and the stability is insufficient because of the deactivation by I 2 adsorption and reaction.…”

Section: Introductionsupporting

confidence: 82%

Pt-Rh/TiO₂ /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

et al. 2018

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Pt-TiO 2 loaded on activated carbon was studied as an active and stable catalyst to HI decomposition for H 2 formation in the sulfur-iodine process. Although the activity of TiO 2 -loaded catalyst was slightly lower HI conversion than that of CeO 2 loaded one, the higher stability against HI decomposition reaction was achieved and almost equilibrium conversion was sustained over~65 h examined. Moreover, effects of Rh or Ir addition on HI conversion were studied and it was found that Pt-Rh bimetallic system was highly active and stable to HI decomposition. Scanning transmission electron micrograph observation suggested that the increased HI decomposition activity was assigned to the increased dispersion of Pt particles. High dispersion state of Pt was sustained after HI decomposition at 773 K by addition of Rh. Since the formation of PtI 4 was suggested by X-ray photoelectron spectroscopy measurement during HI decomposition, increased stability by addition of Rh seems to be assigned to the high chemical stability of Rh against iodine. Almost the equilibrium HI conversion on Pt-Rh-TiO 2 /M563 was sustained over 300 hours at 673 K.

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Section: Introductionsupporting

confidence: 82%

Pt-Rh/TiO₂ /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

et al. 2018

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“…The influence of operating temperature on the electrolytic performance was analyzed in two opposite aspects. First, increase in temperature enhances the activity of species in the solution and increases the reaction kinetic rate because of the endothermic characteristic of HI decomposition . On contrary, the rising temperature reduces the local current density according to Equation .…”

Section: Resultsmentioning

confidence: 99%

Modeling and experimental assessment of the novel HI‐I ₂ ‐H ₂ O electrolysis for hydrogen generation in the sulfur‐iodine cycle

et al. 2020

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Summary To improve the sulfur‐iodine (SI or IS) cycle for renewable hydrogen production, direct electrolysis of HIx solution (HI‐I2‐H2O) from Bunsen reaction has been recently proposed. This work concerns the detailed microscopic physical performance and electrolytic processes of HIx electrolysis through theoretical simulation and experimental exploration. A two‐dimensional mathematical model of the electrolytic cell for HIx electrolysis was developed, and was verified by the relevance between the simulated and experimental hydrogen production. The concentration, electric and flow field distributions were characterized. The decrease of anodic HI and increase of cathodic H2 were found along the flow direction. The local potential distribution declined from anode to cathode region. Higher pressure drop from the inlet to outlet of channel as well as the pumping power were required for anolyte than catholyte. More detailed electrolytic processes along the flow channel at different operating conditions were analyzed. Increasing temperature from 303 K to 343 K improved the H2 production rate. A low anode flow rate of 0.2 m/s was favorable for achieving high conversion rate of reactants and low consumed pumping power. The developed models and the clarified characteristics of HIx electrolysis will be further applied to the improved SI cycle.

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“…Another study measured the boiling heat transfer coefficient of the sulfuric acid solution, which is required to design the sulfuric acid decomposer. Tyagi et al evaluated activity and stability of different catalysts for decomposition of hydriodic acid to choose suitable and stable catalyst for engineering application. Zhang et al proposed a detailed kinetic mechanism of homogeneous sulfuric acid solution decomposition and studied the effects of temperature, SO 3 /H 2 O ratio, residence time, and pressure on the decomposition rate of SO 3 to increase the SO 3 conversion.…”

Section: Introductionmentioning

confidence: 99%

Numerical study of heat transfer and sulfuric acid decomposition in the process of hydrogen production

et al. 2019

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Summary The sulfuric acid decomposer is the key equipment of the iodine‐sulfur cycle to achieve hydrogen production utilizing high temperature of very high‐temperature gas‐cooled reactor (VHTR). This study discusses sulfuric acid decomposer design and pipeline layout to improve the performance of the sulfuric acid decomposer based on a shell‐and‐tube heat exchanger with a bayonet heat exchanger as the core. The finite volume method was used to numerically calculate the heat transfer, temperature distribution, baffle layout, and sulfur trioxide decomposition rate in the sulfuric acid decomposer. The results show that the convective heat transfer coefficient of the fully developed section of the sulfuric acid decomposer for the given conditions is about 10 W·m−2·K−1 and the average temperature of the sulfuric acid in the catalyst region is about 1040 K. For the design, the inlet manifold plate effectively distributes the inlet helium, while the staggered baffles in the shell and tube heat exchanger increase the heat transfer area and improve the helium distribution to enhance the heat transfer. The prediction shows that the sulfur trioxide decomposition rate is about 60% in the catalyst region under design VHTR condition, which is in agreement with experimental measurement under corresponding temperature and space velocity. The results provide a reference for the design of sulfuric acid decomposers for VHTR.

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Pt/graphite catalyst for hydrogen generation by HI decomposition reaction in S-I thermochemical cycle

Cited by 13 publications

References 43 publications

Pt-Rh/TiO₂ /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

Pt-Rh/TiO₂ /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

Modeling and experimental assessment of the novel HI‐I ₂ ‐H ₂ O electrolysis for hydrogen generation in the sulfur‐iodine cycle

Numerical study of heat transfer and sulfuric acid decomposition in the process of hydrogen production

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Pt/graphite catalyst for hydrogen generation by HI decomposition reaction in S-I thermochemical cycle

Cited by 13 publications

References 43 publications

Pt-Rh/TiO2 /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

Pt-Rh/TiO2 /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

Modeling and experimental assessment of the novel HI‐I 2 ‐H 2 O electrolysis for hydrogen generation in the sulfur‐iodine cycle

Numerical study of heat transfer and sulfuric acid decomposition in the process of hydrogen production

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Pt-Rh/TiO₂ /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

Pt-Rh/TiO₂ /activated carbon as highly active and stable HI decomposition catalyst for hydrogen production in sulfur-iodine (SI) process

Modeling and experimental assessment of the novel HI‐I ₂ ‐H ₂ O electrolysis for hydrogen generation in the sulfur‐iodine cycle