TY - EJOU
AU - Tan, Hao
AU - Huang, Zeai
AU - Gong, Runxian
AU - Mei, Junming
AU - Wu, Kejie
AU - Yan, Tianyu
AU - Zhu, Daoquan
AU - Zhang, Zhibin
AU - Zhang, Ruiyang
TI - Research Advances in the Application of Non-Nickel-Based Perovskite Materials for Biogas Reforming
T2 - Energy Engineering
PY - 2025
VL - 122
IS - 11
SN - 1546-0118
AB - Under the driving goal of carbon neutrality, biogas reforming technology has garnered significant attention due to its ability to convert greenhouse gases (CH4/CO2) into syngas (H2/CO). Conventional nickel-based catalysts suffer from issues such as carbon deposition, sintering and sulfur poisoning. Non-nickel-based perovskite materials, with their tunable crystal structure, dynamic oxygen vacancy characteristics, and excellent anti-coking/anti-sulfur performance, have emerged as a promising alternative. This review systematically summarizes the design for non-nickel-based perovskite materials, including optimizing lattice oxygen migration ability and active site stability by A/B site doping, defect engineering and heterojunction construction. The enhancing the conversion rate of CH4/CO2 by using the carbon oxidation mechanism mediated by oxygen vacancies, and maintaining good durability in complex biogas environments containing H2S, NH3, etc. The photo-thermal synergistic catalysis further improves the reaction efficiency through energy coupling. However, challenges such as long-term operational stability (high-temperature lattice reconstruction), the cost of large-scale preparation and the synergistic poisoning effect of sulfur and water are still challenges for practical application. In the future, it is necessary to combine high-throughput computation, in situ characterization and multi-technology coupling to promote the leap of non-nickel-based perovskites materials from laboratory to industrial biogas reforming units.
KW - Non-nickel-based perovskites; biogas reforming; oxygen vacancies; anti-coking; photothermal synergistic catalysis
DO - 10.32604/ee.2025.070226