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1. Singh, S., Mohan Prasad, S. & Pratap Singh, V. Additional calcium and sulfur manages hexavalent chromium toxicity in Solanum lycopersicum L. and Solanum melongena L. seedlings by involving nitric oxide. Journal of Hazardous Materials 398, 122607 (2020).

2. Ariyarathna, R. a. I. S., Weerasena, S. L. & Beneragama, C. K. Application of Polyphasic OJIP Chlorophyll Fluorescent Transient Analysis as an Indicator for Testing of Seedling Vigour of Common Bean (Phaseolus vulgaris L.). Tropical Agricultural Research 31, 106¨C115 (2020).

3. Prity, S. A. et al. Arbuscular mycorrhizal fungi mitigate Fe deficiency symptoms in sorghum through phytosiderophore-mediated Fe mobilization and restoration of redox status. Protoplasma (2020) doi:10.1007/s00709-020-01517-w.

4. Rahman, M. A. et al. Arbuscular Mycorrhizal Symbiosis Mitigates Iron (Fe)-Deficiency Retardation in Alfalfa (Medicago sativa L.) Through the Enhancement of Fe Accumulation and Sulfur-Assisted Antioxidant Defense. International Journal of Molecular Sciences 21, 2219 (2020).

5. Vitorino, L. C. et al. Biocontrol Potential of Sclerotinia sclerotiorum and Physiological Changes in Soybean in Response to Butia archeri Palm Rhizobacteria. Plants 9, 64 (2020).

6. Aalifar, M. et al. Blue Light Improves Vase Life of Carnation Cut Flowers Through Its Effect on the Antioxidant Defense System. Front. Plant Sci. 11, 511 (2020).

7. Muthusamy, M., Yoon, E. K., Kim, J. A., Jeong, M.-J. & Lee, S. I. Brassica Rapa SR45a Regulates Drought Tolerance via the Alternative Splicing of Target Genes. Genes 11, 182 (2020).

8. Muthusamy, M., Kim, J. Y., Yoon, E. K., Kim, J. A. & Lee, S. I. BrEXLB1, a Brassica rapa Expansin-Like B1 Gene Is Associated with Root Development, Drought Stress Response, and Seed Germination. Genes 11, 404 (2020).

9. Herritt, M. T. & Fritschi, F. B. Characterization of Photosynthetic Phenotypes and Chloroplast Ultrastructural Changes of Soybean (Glycine max) in Response to Elevated Air Temperatures. Front. Plant Sci. 11, (2020).

10.Kasampalis, D. S., Tsouvaltzis, P. & Siomos, A. S. Chlorophyll fluorescence, non-photochemical quenching and light harvesting complex as alternatives to color measurement, in classifying tomato fruit according to their maturity stage at harvest and in monitoring postharvest ripening during storage. Postharvest Biology and Technology 161, 111036 (2020).

11.Soares, J. S., Santiago, E. F. & Sorgato, J. C. Conservation of Schomburgkia crispa Lindl. (Orchidaceae) by reintroduction into a fragment of the Brazilian Cerrado. Journal for Nature Conservation 53, 125754 (2020).

12.Poblete, T. et al. Detection of Xylella fastidiosa infection symptoms with airborne multispectral and thermal imagery: Assessing bandset reduction performance from hyperspectral analysis. ISPRS Journal of Photogrammetry and Remote Sensing 162, 27¨C40 (2020).

13.Chiluwal, A. et al. Deterioration of ovary plays a key role in heat stress-induced spikelet sterility in sorghum. Plant, Cell & Environment 43, 448¨C462 (2020).

14.Maai, E., Nishimura, K., Takisawa, R. & Nakazaki, T. Diurnal changes in chloroplast positioning and photosynthetic traits of C4 grass finger millet. Plant Production Science 0, 1¨C13 (2020).

15.De Micco, V. et al. Dust accumulation due to anthropogenic impact induces anatomical and photochemical changes in leaves of Centranthus ruber growing on the slope of the Vesuvius volcano. Plant Biol J 22, 93¨C102 (2020).

 

¸½£ºOJIP²ÎÊý¼°ÅÌË㹫ʽ

• Bckg = background
• Fo: = F50?s; fluorescence intensity at 50 ?s
• Fj: = fluorescence intensity at j-step (at 2 ms)
• Fi: = fluorescence intensity at i-step (at 60 ms)
• Fm: = maximal fluorescence intensity
• Fv: = Fm - Fo (maximal variable fluorescence)
• Vj = (Fj - Fo) / (Fm - Fo)
• Fm / Fo = Fm / Fo
• Fv / Fo = Fv / Fo
• Fv / Fm = Fv / Fm
• Mo = TRo / RC - ETo / RC
• Area = area between fluorescence curve and Fm
• Sm = area / Fm - Fo (multiple turn-over)
• Ss = the smallest Sm turn-over (single turn-over)
• N = Sm . Mo . (I / Vj) turn-over number QA
• Phi_Po = (I - Fo) / Fm (or Fv / Fm)
• Phi_o = I - Vj
• Phi_Eo = (I - Fo / Fm) . Phi_o
• Phi_Do = 1 - Phi_Po - (Fo / Fm)
• Phi_Pav = Phi_Po - (Sm / tFM); tFM = time to reach Fm (in ms)
• ABS / RC = Mo . (I / Vj) . (I / Phi_Po)
• TRo / RC = Mo . (I / Vj)
• ETo / RC = Mo . (I / Vj) . Phi_o)
• DIo / RC = (ABS / RC) - (TRo / RC)