Sorption-enhanced steam reforming of toluene using multifunctional perovskite phase transition sorbents in a chemical looping scheme

IF 7 3区 材料科学 Q1 ENERGY & FUELS Journal of Physics-Energy Pub Date : 2023-06-14 DOI:10.1088/2515-7655/acdbe9
Leo Brody, Mahe Rukh, R. Cai, Azin Saberi Bosari, R. Schomäcker, Fanxing Li
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Abstract

Sorption-enhanced steam reforming (SESR) of toluene (SESRT) using catalytic CO2 sorbents is a promising route to convert the aromatic tar byproducts formed in lignocellulosic biomass gasification into hydrogen (H2) or H2-rich syngas. Commonly used sorbents such as CaO are effective in capturing CO2 initially but are prone to lose their sorption capacity over repeated cycles due to sintering at high temperatures. Herein, we present a demonstration of SESRT using A- and B-site doped Sr1−x A’ x Fe1−y B’ y O3−δ (A’ = Ba, Ca; B’ = Co) perovskites in a chemical looping scheme. We found that surface impregnation of 5–10 mol% Ni on the perovskite was effective in improving toluene conversion. However, upon cycling, the impregnated Ni tends to migrate into the bulk and lose activity. This prompted the adoption of a dual bed configuration using a pre-bed of NiO/γ–Al2O3 catalyst upstream of the sorbent. A comparison is made between isothermal operation and a more traditional temperature-swing mode, where for the latter, an average sorption capacity of ∼38% was witnessed over five SESR cycles with H2-rich product syngas evidenced by a ratio of H2: CO x > 4.0. XRD analysis of fresh and cycled samples of Sr0.25Ba0.75Fe0.375Co0.625O3-δ reveal that this material is an effective phase transition sorbent—capable of cyclically capturing and releasing CO2 without irreversible phase changes occurring.
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多功能钙钛矿相变吸附剂在化学循环方案中对甲苯的吸附增强水蒸气重整
使用催化CO2吸收剂的甲苯吸附增强蒸汽重整(SESR)是将木质纤维素生物质气化中形成的芳香焦油副产物转化为氢气(H2)或富含H2的合成气的一种很有前途的途径。常用的吸附剂如CaO在最初捕获CO2时是有效的,但由于在高温下烧结,在重复循环中容易失去其吸附能力。在此,我们以化学循环方案使用a和B位掺杂的Sr1−x a’x Fe1−y B’y O3−δ(a’=Ba,Ca;B’=Co)钙钛矿来演示SESRT。我们发现,在钙钛矿上表面浸渍5–10 mol%的Ni可以有效地提高甲苯的转化率。然而,在循环时,浸渍的Ni倾向于迁移到本体中并失去活性。这促使采用双床配置,在吸附剂上游使用NiO/γ–Al2O3催化剂的预床。在等温操作和更传统的温度摆动模式之间进行了比较,其中,对于后者,在五次SESR循环中,富H2的产物合成气的平均吸附能力为~38%,H2:CO x>4.0的比率证明了这一点。对新鲜和循环的Sr0.25Ba0.75Fe0.375Co0.625O3-δ样品的XRD分析表明,该材料是一种有效的相变吸附剂,能够循环捕获和释放CO2,而不会发生不可逆的相变。
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来源期刊
CiteScore
10.90
自引率
1.40%
发文量
58
期刊介绍: The Journal of Physics-Energy is an interdisciplinary and fully open-access publication dedicated to setting the agenda for the identification and dissemination of the most exciting and significant advancements in all realms of energy-related research. Committed to the principles of open science, JPhys Energy is designed to maximize the exchange of knowledge between both established and emerging communities, thereby fostering a collaborative and inclusive environment for the advancement of energy research.
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