Physic nut (Jatropha curcas L.) is one of the main crops which could provide biodiesel as an energy crop. It origins from tropical America and widely distributes in tropical and subtropical areas of Asia and Africa. Low temperatures in winter and early spring will inhibit the growth and development of physic nut. To understand the physiological responses such as photoinhibition of physic nut at different temperatures with high light intensity, cut stems of physic nut were used for propagation in this research. First, the pigment contents and the reflectance spectral properties of yellowing leaves subjected to winter cold stress. Second, chlorophyll fluorescence, photochemical reflectance index and vegetation index at different temperatures with high light intensity were evaluated. Third, photo-physiological indexes of young plants of physic nut treated at 7 or 42℃ for 1,2 and 3 days was tested. In the first experiment, the regression analysis of pigment contents and vegetation indexes by spectral reflectance was applied.When the leaves were senescent and yellow, the Chl and Car contents decreased significantly with the yellowing levels. The reflectance spectra showed that the reflectance of visible band was increased and the reflectance of NIR band was decreased. The normalized difference vegetation index (NDVI) was calculated by reflectance at 705 nm and 750 nm and significantly correlated with Chl concentrations (correlation R2 > 0.9). The photo-chemical reflectance index (PRI) was calculated by reflectance at 531 nm and 570 nm and significantly correlated with Car concentrations (correlation R2 > 0.85). Second, the young plants of physic nut under different temperatures with high light intensity would show different morphologies, photo-physiological index, reflectance spectral properties, and chlorophyll fluorescence also could represent different physiological status. In this study the physic nut plants were treated in dark environment at 7,14,21,28,35 and 42℃ for one day. The NDVI calculated by reflectance spectra showed no difference between all temperature treatments with the values between 0.7 to 0.8. The PRI calculated by reflectance spectra and chlorophyll fluorescence were measured before and after 1,800 μmolm-2s-1 PPFD light treatment. The results showed that levels of Fv/Fm,ΦPSII,ETR,qP and PRI decreased, and NPQ increased significantly at 42℃ before light treatment. Levels of Fv/Fm were decreased significantly to 40 to 50%. The trend of chlorophyll fluorescence of physic nut at 7℃ under 1,800 PPFD equals to those tested at 42℃. Third, young plants of physic nut were tested at 7 or 42℃ treatment for 1,2 and 3 days. The results showed that NDVI had no difference between all temperatures and day durations. The PRI variation before and after illumination were higher in the 42℃ treatment for 1,2 and 3 days than those in the 7℃ treatments. The net CO2 assimilation rate (Pn) approached zero at 7℃ for the second day, and the Pn decreased significantly at 42℃ for the third day. Physic nut was more tolerant at 42℃ than 7℃. The ΦPSII of chlorophyll fluorescence was significantly correlated with Pn (R2 > 0.754, P < 0.0001). From the results, we could use the NDVI and PRI, calculated by reflectance spectra, to estimate the contents of Chl and Car in the young plants of physic nut. We could also quickly monitor the physiological status of physic nut plants at different temperatures by the levels of chlorophyll fluorescence for the high correlation between ΦPSII and Pn.