TY - JOUR
T1 - Dual-site engineering of Ga-modified HZSM-5 towards efficient propane aromatization
AU - Ge, Zhaoshuo
AU - Bao, Lixia
AU - Lv, Yangping
AU - Wu, Yiheng
AU - Shi, Daxin
AU - Liu, Qi
AU - Wu, Qin
AU - Chen, Kangcheng
AU - Jiang, Guiyuan
AU - Li, Hansheng
AU - Zhang, Yaoyuan
N1 - Publisher Copyright:
© 2026 The Chemical Industry and Engineering Society of China, and Chemical Industry Press Co., Ltd.
PY - 2026/5
Y1 - 2026/5
N2 - Light alkane aromatization represents a pivotal catalytic process for valorizing abundant light alkanes into high-value aromatics, holding significant industrial promise. Herein, a series of Ga-HZSM-5 catalysts were synthesized by the hydrothermal method. The effects of Ga content and Si/Al ratio on the catalytic performance of propane aromatization over Ga-HZSM-5 were investigated to discern the structure-activity relationship, reaction pathway, and coke formation. The optimized 1%Ga-HZSM-5(50) catalyst exhibited superior performance, with propane conversion and BTX formation showing a volcano-shaped trend with increasing Ga content. Conversely, for a fixed Ga loading, aromatization performance was enhanced with decreasing Si/Al ratio, with 1%Ga-HZSM-5(25) delivering the highest aromatization activity. A positive correlation was identified between catalytic activity and Lewis acid density, underscoring the role of Lewis sites in facilitating propane dehydrogenation and subsequent BTX formation. Furthermore, TG and TPO analyses revealed that the deposited coke in Ga-HZSM-5 was predominantly highly graphitized, which could not be removed by the air-regeneration treatment under reaction temperature.
AB - Light alkane aromatization represents a pivotal catalytic process for valorizing abundant light alkanes into high-value aromatics, holding significant industrial promise. Herein, a series of Ga-HZSM-5 catalysts were synthesized by the hydrothermal method. The effects of Ga content and Si/Al ratio on the catalytic performance of propane aromatization over Ga-HZSM-5 were investigated to discern the structure-activity relationship, reaction pathway, and coke formation. The optimized 1%Ga-HZSM-5(50) catalyst exhibited superior performance, with propane conversion and BTX formation showing a volcano-shaped trend with increasing Ga content. Conversely, for a fixed Ga loading, aromatization performance was enhanced with decreasing Si/Al ratio, with 1%Ga-HZSM-5(25) delivering the highest aromatization activity. A positive correlation was identified between catalytic activity and Lewis acid density, underscoring the role of Lewis sites in facilitating propane dehydrogenation and subsequent BTX formation. Furthermore, TG and TPO analyses revealed that the deposited coke in Ga-HZSM-5 was predominantly highly graphitized, which could not be removed by the air-regeneration treatment under reaction temperature.
KW - Molecular sieves
KW - Propane aromatization
KW - Reaction pathway
KW - Reactivity
KW - Stability
KW - Structure-activity relationship
UR - https://www.scopus.com/pages/publications/105037761861
U2 - 10.1016/j.cjche.2025.12.008
DO - 10.1016/j.cjche.2025.12.008
M3 - Article
AN - SCOPUS:105037761861
SN - 1004-9541
VL - 93
SP - 352
EP - 362
JO - Chinese Journal of Chemical Engineering
JF - Chinese Journal of Chemical Engineering
ER -