光合作用
作物生产力
碳同化
纳米技术
同化(音韵学)
生化工程
化学
拟南芥
过程(计算)
碳纳米管
环境科学
计算机科学
生产力
作物
纳米颗粒
生物物理学
合理设计
光合效率
材料科学
植物种类
作者
Thi Linh Chi Tran,Lingxue Kong,Wenrong Yang,David M. Cahill
出处
期刊:Nano Today
[Elsevier BV]
日期:2026-02-12
卷期号:68: 103003-103003
标识
DOI:10.1016/j.nantod.2026.103003
摘要
Enhancing photosynthesis, a fundamental process to convert light energy into chemical energy, is a frontier approach to increasing crop productivity. In recent years, nanoparticles (NPs) have emerged as promising tools to modulate photosynthetic performance, yet the mechanistic pathways connecting NP-plant interactions to photosynthetic responses remain unclear. Here, we provide an integrated synthesis of recent research on the impacts of NPs on photosynthesis from subcellular to whole plant level, an across-scale perspective that has been less systematically addressed in prior reviews. The effects of most investigated non-organic NP classes, including carbon-based such as carbon dots and carbon nanotubes and metal-based NPs such as SiO 2 , MoO 3 , ZnO, and Ag NPs are examined. Across both crop species such as lettuce and rice and model plants such as Arabidopsis and tobacco, we compare reported optimal concentrations (typically 10–100 mg/L) and emphasize the importance of appropriate controls, including untreated plants, bulk-material and ionic counterparts. Notably, this review delves into how NPs can enhance photosynthesis through both direct and indirect mechanism. It involves deeper consideration of how NPs influence light harvesting and photoconversion, excitation-energy regulation, electron transport, and thereby downstream impacts on CO 2 assimilation and the Calvin-Benson-Bassham (CBB) cycle. Common methods used to evaluate photosynthetic performance following NP treatments, as well as the relationship between NP uptake and their effects on photosynthesis, were also critically assessed. Overall, this review highlights how NP application and the rational design of targeted NP-based systems could improve photosynthesis and, in turn, enhance crop productivity and resilience under a changing climate. • Summarizes the NP impacts on photosynthesis and growth from subcellular to whole-plant scales. • Highlights direct and indirect mechanisms of NPs interaction photosynthetic machinery. • Discusses methods to evaluate photosynthesis after NP exposure and relates NP uptake to photosynthetic responses.
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