Original paper

1. Kinose Y., Seita R., 2022.
   Simulating the impacts of and adaptation options for increasing air temperature on chalky rice grains in the Kyushu region of Japan.
   Journal of Agricultural Meteorology (Accepted on 29 June 2022).

2. Watanabe M., Li J., Matsumoto M., Aoki T., Ariura R., Fuse T., Zhang Y., Kinose Y., Yamaguchi M., Izuta T., 2022.
   Growth and photosynthetic responses to ozone of Siebold’s beech seedlings grown under elevated CO₂ and soil nitrogen supply.
   Environmental Pollution 304, 119233. DOI: 10.1016/j.envpol.2022.119233
   

3. Kataoka R., Akashi M., Taniguchi T., Kinose Y., Yaprak A.E., Turgay O.C., 2021.
   Metabolomics analyses reveal metabolites affected by plant growth-promoting endophytic bacteria in roots of the halophyte Mesembryanthemum crystallinum.
   International Journal of Molecular Sciences 22, 11813. DOI: 10.3390/ijms222111813
   

4. Watanabe M., Hiroshima H., Kinose Y., Okabe S., Izuta T., 2020.
   Nitrogen use efficiency for growth of Fagus crenata seedlings under elevated ozone and different soil nutrient conditions.
   Forests, 11, 371. DOI: 10.3390/f11040371
   

5. Kinose Y., Fukamachi Y., Okabe S., Hiroshima H., Watanabe M., Izuta T., 2020.
   Toward an impact assessment of ozone on plant carbon fixation using a process-based plant growth model: A case study of Fagus crenata grown under different soil nutrient levels.
   Science of the Total Environment 716, 137008. DOI: 10.1016/j.scitotenv.2020.137008
   

6. Kinose Y., Yamaguchi M., Matsumura H., Izuta T., 2020.
   Impact assessment of ozone absorbed through stomata on photosynthetic carbon dioxide uptake by Japanese deciduous forest trees: Implications for ozone mitigation policies.
   Forests 11, 137. DOI: 10.3390/f11020137
   

7. Kinose Y., Fukamachi Y., Watanabe M., Izuta T., 2020.
   Ozone-induced change in the relationship between stomatal conductance and net photosynthetic rate is a factor determining cumulative stomatal ozone uptake by Fagus crenata seedlings.
   Trees - Structure and Function 34, 445–454. DOI: 10.1007/s00468-019-01927-1
   

8. Kinose Y., Masutomi Y., Shiotsu F., Hayashi K., Ogawada D., Gomez-Garcia M., Matsumura A., Takahashi K., Fukushi K., 2020
   Impact assessment of climate change on the major rice cultivar Ciherang in Indonesia.
   Journal of Agricultural Meteorology 76, 19–28. DOI: 10.2480/agrmet.D-19-00045
   

9. Tatsumi K., Abiko T., Kinose Y., Inagaki S., Izuta T., 2019
   Effects of ozone on the growth and yield of rice (Oryza sativa L.) under different nitrogen fertilization regimes.
   Environmental Science and Pollution Research 26, 32103–32113. DOI: 10.1007/s11356-019-06358-6
   

10. Kamal M.Z.U., Yamaguchi M., Kinose Y., Izuta T., 2019.
    Mitigation mechanism of ozone-induced reduction in net photosynthesis of Bangladeshi wheat under soil salinity stress.
    Photosynthetica (Accepted)
    

11. Yamaguchi M., Kinose Y., Matsumura H., Izuta T., 2019.
    Evaluation of O₃ effects on cumulative photosynthetic CO₂ uptake in seedlings of four Japanese deciduous broad-leaved forest tree species based on stomatal O₃ uptake.
    Forests 10, 556. DOI: 10.3390/f10070556
    

12. Masutomi Y., Kinose Y., Takimoto T., Yonekura T., Oue H., Kobayashi K., 2019
    Ozone changes the linear relationship between photosynthesis and stomatal conductance and decreases water use efficiency in rice.
    Science of the Total Environment 655, 1009-1016. DOI: 10.1016/j.scitotenv.2018.11.132
    

13. Watanabe M., Okabe S., Kinose Y., Hiroshima H., Izuta T., 2018
    Effects of ozone on soil respiration rate of Siebold’s beech seedlings grown under different soil nutrient conditions.
    Journal of Agricultural Meteorology (Accepted on 20 August) DOI: 10.2480/agrmet.D-18-00009
    

14. Watanabe M., Kamimaki Y., Mori M., Okabe S., Arakawa I., Kinose Y., Nakaba S., Izuta T., 2018.
    Mesophyll conductance to CO₂ in leaves of Siebold's beech (Fagus crenata) seedlings under elevated ozone.
    Journal of Plant Research 131, 907-914. DOI: 10.1007/s10265-018-1063-4
    

15. Watanabe M., Kinose Y., Izuta T., 2018.
    Photosynthesis of three evergreen broad-leaved tree species, Castanopsis sieboldii, Quercus glauca, and Q. myrsinaefolia, under elevated ozone.
    iForest - Biogeosciences and Forestry 11, 360–366. DOI: 10.3832/ifor2493-011
    

16. Kinose Y., Fukamachi Y., Okabe S., Hiroshima H., Watanabe M., Izuta T., 2017.
    Photosynthetic responses to ozone of upper and lower canopy leaves of Fagus crenata Blume seedlings grown under different soil nutrient conditions.
    Environmental Pollution 223, 213–222. DOI: 10.1016/j.envpol.2017.01.014
    

17. Kinose Y., Fukamachi Y., Okabe S., Hiroshima H., Watanabe M., Izuta T., 2017.
    Nutrient supply to soil offsets the ozone-induced growth reduction in Fagus crenata seedlings.
    Trees - Structure and Function 31, 259–272. DOI: 10.1007/s00468-016-1481-7
    

18. Kamal M.Z.U., Yamaguchi M., Azuchi F., Kinose Y., Wada Y., Funada R., Izuta T., 2015.
    Effects of ozone and soil salinity, singly and in combination, on growth, yield and leaf gas exchange rates of two Bangladeshi wheat cultivars.
    Asian Journal of Atmospheric Environment 9, 173–186. DOI: 10.5572/ajae.2015.9.2.173
    

19. Kinose Y., Azuchi F., Uehara Y., Kanomata T., Kobayashi A., Yamaguchi M., Izuta T., 2014.
    Modeling of stomatal conductance to estimate stomatal ozone uptake by Fagus crenata, Quercus serrata, Quercus mongolica var. crispula and Betula platyphylla.
    Environmental Pollution 194, 235–245. DOI: 10.1016/j.envpol.2014.07.030
    

20. Azuchi F., Kinose Y., Matsumura T., Kanomata T., Uehara Y., Kobayashi A., Yamaguchi M., Izuta T., 2014.
    Modeling stomatal conductance and ozone uptake of Fagus crenata grown under different nitrogen loads.
    Environmental Pollution 184, 481–487. DOI: 10.1016/j.envpol.2013.09.025
    

Review

1. ​Agathokleous E., Kitao M., Kinose Y., 2018.
   A review study on ozone phytotoxicity metrics for setting critical levels in Asia.
   Asian Journal of Atmospheric Environment 12, 1–16. DOI: 10.5572/ajae.2018.12.1.001
   

Book

1. 米倉哲志, 黄瀬佳之, 山口真弘, 伊豆田 猛. 2020.
   農作物に対するオゾンの影響.
   伊豆田 猛 編, 大気環境と植物, 朝倉書店, 東京, 1–9.
   

2. 黄瀬佳之, 渡辺 誠, 山口真弘, 伊豆田 猛. 2020.
   樹木に対するオゾンの影響.
   伊豆田 猛 編, 大気環境と植物, 朝倉書店, 東京, 10–17.
   

3. 黄瀬佳之, 渡辺 誠, 山口真弘, 伊豆田 猛. 2020.
   植物に対するオゾンと環境要因の複合影響.
   伊豆田 猛 編, 大気環境と植物, 朝倉書店, 東京, 18–26.
   

4. Kinose Y., ​Masutomi Y., 2019.
   Impact assessment of climate change on rice yield using a crop growth model and activities toward adaptation: Targeting three provinces in Indonesia.
   Iizumi T., Hirata R., Matsuda R. (eds.), Adaptation to Climate Change in Agriculture, Springer, Singapore, 67–80. DOI: 10.1007/978-981-13-9235-1
   

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