To meet the escalating food and fuel demands of a growing global population and industry, food production requires a 50% increase by 2050. However, various environmental stresses, such as excessive light, significantly inhibit plant growth and lead to substantial reductions in crop yields. A major contributing factor to such declines is the reduction in photosynthetic capacity. In this study, a chemical-screening system based on standard 96-well plate and tobacco leaf tissue was developed. With this system, several anthraquinone derivatives that could alleviate high light stress from plants were identified. Application of these chemicals induced greater photosynthetic capacities and better plant growth during and after exposure to light stress for 20-96 hours in tobacco, lettuce, tomato and Arabidopsis. Mechanistic investigations unveiled that these chemicals exhibited electron-accepting abilities at PSI in vitro and improve PSI efficiency in vivo, indicating that the photoprotective effect could be a result of PSI acceptor side oxidation induced by these chemicals. Meanwhile, no adverse effects on plant growth were observed in chemical treated plants under non-stressful cultivation conditions. This study implies that anthraquinone derivatives can confer high light stress tolerance in plants, resulting in improved plant photosynthesis and growth in light stress environments.