Redox-mediated reverse water gas shift integrated with ammonia cracking over Ni/La0.75Sr0.25Cr0.5Mn0.5O3−δ

IF 5.5 Q1 ENGINEERING, CHEMICAL

Chemical Engineering Journal Advances Pub Date : 2025-02-03 DOI:10.1016/j.ceja.2025.100713

Martin Keller , Shih-Yuan Chen , Atul Sharma

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Abstract

NH₃ and CO₂ can react to produce syngas (H₂ + CO), which serves as a feedstock for the production of chemicals or synthetic fuels. Combining NH₃ cracking (NH₃ → 0.5N₂ + 1.5H₂) and the redox-mediated reverse water gas shift reaction (RWGS, CO₂ + H₂ → CO + H₂O), we propose the “NH₃-RWGS” process in a two-reactor system that can produce N₂-free syngas without requiring a downstream gas separation step. We investigate the role of La_0.75Sr_0.25Cr_0.5Mn_0.5O_3−δ (LSCM) in the redox-mediated RWGS, combined with a stabilized Ni catalyst to impart NH₃ cracking functionality. The mixture of LSCM and Ni catalyst at a weight ratio of 10:1 increases the NH₃ cracking activity fivefold compared to using only LSCM. Because the reduction of LSCM proceeds through a two-step mechanism that requires the prior cracking of NH₃, it also substantially increases the redox reactivity of LSCM. The Ni catalyst exhibits undesirable nitrogen uptake at ∼500 °C, and the redox capacity of LSCM with NH₃ and CO₂ decreases with temperature. Therefore, the process is best implemented at ∼600 °C. Under these conditions, the application of the “NH₃-RWGS” process with mixtures of LSCM and Ni catalyst is promising to produce high-quality, N₂-free syngas directly from NH₃ and CO₂.

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在Ni/La0.75Sr0.25Cr0.5Mn0.5O3−δ上氧化还原介导的反水气转换与氨裂解相结合

NH3和CO2可以反应产生合成气（H2 + CO），作为生产化学品或合成燃料的原料。结合NH3裂解（NH3→0.5N2 + 1.5H2）和氧化还原介导的反水煤气变换反应（RWGS, CO2 + H2→CO + H2O），提出了双反应器系统中的“NH3-RWGS”工艺，该工艺无需下游气体分离步骤即可生产无n2合成气。我们研究了La0.75Sr0.25Cr0.5Mn0.5O3−δ (LSCM)在氧化还原介导的RWGS中的作用，并结合稳定的Ni催化剂赋予NH3裂解功能。与仅使用LSCM相比，LSCM与Ni催化剂的重量比为10:1时，NH3裂解活性提高了5倍。由于LSCM的还原是通过两步机制进行的，这需要NH3的预先裂解，这也大大提高了LSCM的氧化还原反应性。在~ 500°C时，Ni催化剂表现出不良的氮吸收，LSCM与NH3和CO2的氧化还原能力随温度的升高而降低。因此，该工艺最好在~ 600°C下实施。在此条件下，LSCM和Ni催化剂混合的“NH3- rwgs”工艺有望直接从NH3和CO2中生产出高质量的无n2合成气。

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