Lattice oxygen activity regulation by alkaline earth metals in iron oxides for biomass chemical looping gasification

Carbon Capture Science & Technology Pub Date : 2024-12-16 DOI:10.1016/j.ccst.2024.100353

Guangyao Yang , Wenjie Xu , Jingbo Jia , Changfu You , Haiming Wang

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Abstract

Biomass chemical looping gasification (BCLG) represents a highly promising approach for syngas production. A critical factor in BCLG is the selection of suitable oxygen carriers (OCs) that exhibit both high carbon conversion (η_C) and CO selectivity (S_CO). In this study, iron-based OCs were modified with various alkaline earth metals (AEMs, i.e. Ca, Sr, and Ba) to modulate lattice oxygen activity. The effects of oxygen-to-carbon ratio (O/C), temperature, and cyclic operation on BCLG performance were investigated in a fixed-bed reactor. Among the AEM-modified OCs, Ca1Fe2 (spinel), Sr1Fe1 (perovskite), and Ba1Fe2 (spinel), showed superior performance compared to their Ca, Sr, and Ba-Fe counterparts, respectively. At 900 °C and O/C = 2, the pristine Fe₂O₃ exhibited a η_C of 82 % and S_CO of 53 %. The η_C for Sr1Fe1 and Ba1Fe2 reached >90 % at 900 °C, with S_CO increased to >70 %, resulting in a significantly higher syngas yield (H₂+CO) of >800 mL/g-biomass (vs. 560 for Fe₂O₃). In contrast, the addition of Ca showed a much less pronounced effect. In the cyclic test at 900 °C, Ba1Fe2 showed the poorest stability due to a severe sintering. Sr1Fe1 presented the best stability with a syngas yield of 722 mL/g after 10 cycles. The decrease in the activity of Sr1Fe1 was mainly due to the phase separation of SrFeO_3-x after multiple cycles. Thermodynamically, Sr1Fe1 is favorable for the production of CO instead of CO₂, leading to its intrinsic high selectivity. As demonstrated by ¹⁸O-isotopic exchange and H₂-TPR, the activity of surface lattice oxygen and the diffusivity of bulk lattice oxygen was boosted by Sr addition, which caused the high η_C and S_CO of Sr1Fe1 at the same time. Thus, even at O/C=5, S_CO for Sr1Fe1 reached 64 % with η_C up to 99 %, comparing to the S_CO=31 % and η_C=91 % for Fe₂O₃.

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生物质化学环气化中氧化铁中碱土金属对晶格氧活性的调节

生物质化学环气化（BCLG）是一种非常有前途的合成气生产方法。BCLG的一个关键因素是选择合适的氧载体（OCs），同时表现出高碳转化率（ηC）和CO选择性（SCO）。在本研究中，用各种碱土金属（AEMs，即Ca， Sr和Ba）修饰铁基OCs以调节晶格氧活性。在固定床反应器中研究了氧碳比（O/C）、温度和循环操作对BCLG性能的影响。在aem修饰的OCs中，Ca1Fe2（尖晶石）、Sr1Fe1（钙钛矿）和Ba1Fe2（尖晶石）分别表现出优于Ca、Sr和Ba-Fe的性能。在900℃和O/C = 2时，原始Fe2O3的ηC为82%，SCO为53%。在900℃时，Sr1Fe1和Ba1Fe2的ηC达到90%，SCO提高到70%，导致合成气产率（H2+CO）达到800 mL/g （Fe2O3为560 mL/g）。相比之下，添加钙的效果要弱得多。在900℃的循环试验中，由于烧结严重，Ba1Fe2表现出最差的稳定性。Sr1Fe1稳定性最好，循环10次后合成气产率为722 mL/g。Sr1Fe1活性的下降主要是由于多次循环后SrFeO3-x的相分离。从热力学角度看，Sr1Fe1有利于CO的生成而不是CO2的生成，这使得Sr1Fe1具有固有的高选择性。18o同位素交换和H2-TPR结果表明，Sr的加入提高了表面晶格氧的活性和体晶格氧的扩散率，同时导致Sr1Fe1的高ηC和SCO。因此，即使在O/C=5时，Sr1Fe1的SCO为64%，ηC高达99%，而Fe2O3的SCO为31%，ηC为91%。

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Carbon Capture Science & Technology

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