活性氧
单线态氧
氧气
化学
光化学
电子转移
动力学
产量(工程)
活化能
再分配(选举)
吸附
电荷(物理)
活动中心
催化作用
电子传输链
化学物理
级联
反应速率常数
反应中间体
合理设计
纳米技术
活动站点
激活剂(遗传学)
生物物理学
纳米颗粒
活性氧
激进的
作者
Juan Guo,Xueting Pan,Quan Guo,Chunhui Li,Yun Sun,H X Liu
摘要
ABSTRACT Ultrasound (US)‐triggered reactive oxygen species (ROS) generation by nano‐sonocatalysts is vital for sonocatalytic therapy. However, the therapeutic effect is hindered by the low ROS generation yield owing to sluggish charge transfer and elusive active sites. Herein, in situ oxygen vacancies (Vo)‐engineered Pd‐TiO 2 sonocatalysts with spatially separated dual reactive sites are developed, which optimize charge kinetics and amplify ROS generation. Mechanism studies revealed that US‐induced Vo serves as an electron pump, activating the Pd–O–Ti transport channel, lowering interfacial barriers and steering electron migration from TiO 2 to Pd. This ordered charge redistribution tunes the d ‐band center of Pd, designating electron‐rich Pd sites as the primary active center for O 2 adsorption and activation to produce singlet oxygen ( 1 O 2 ). Concurrently, Vo‐mediated reconstruction of Ti 3d states strengthens orbital coupling with H 2 O at the Pd–O–Ti interface, dominating the activation of H 2 O to promote the generation of hydroxyl radical (•OH). This dual‐site configuration effectively lowers the activation energy barriers, which increases the rate constants of 1 O 2 and •OH generation by 5.0‐fold and 2.7‐fold, respectively, and ultimately achieving an 87.5% tumor inhibition efficiency. This work provides molecular insights into the charge transfer cascade and critical active centers in US‐activated Pd‐TiO 2 , offering a rational paradigm for designing high‐performance sonocatalysts.
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