査読付論文

1. 藤井 賢彦 (2022), 地球温暖化・海洋酸性化・貧酸素化が海洋生態系に及ぼす影響, 沿岸海洋研究, 60(1), 51-60.
2. Yasir Haya, L. O. M., B. Sadarun, M. Tadjudah, A. Kangkuso, L. O. Alirman Afu, A. G. Pratikino, A. Takwir, and M. Fujii (2022), Assessing long-term coral reef degradation in Indonesia’s Tiworo strait marine conservation area using remote sensing and rapid appraisal for fisheries approaches, Model. Earth Syst. Environ. DOI: 10.1007/s40808-022-01421-7.
3. Sudo, K., S. Maehara, M. Nakaoka, and M. Fujii (2022), Predicting future shifts in the distribution of tropicalization indicator fish that affect coastal ecosystem services of Japan, Front. Built Environ., 7, 788700. doi:10.3389/fbuil.2021.788700
4. Endo, A., M. Yamada, K. Baba, Y. Miyashita, R. Sugimoto, A. Ishii, J. Nishijima, M. Fujii, T. Kato, H. Hamamoto, M. Kimura, T. Kumazawa, N. Masuhara, and H. Honda (2021), Methodology for Nexus Approach Toward Sustainable Use of Geothermal Hot Spring Resources, Frontiers in Water, 3, 713000, DOI:10.3389/frwa.2021.713000.
5. Avtar, R., M. Navia, J. Sassen, and M. Fujii (2021), Assessment of changes in mangrove ecosystems in the Ba and Rewa deltas, Fiji, and their impacts using information from multiple sources, Coastal Engineering Journal, 63(3), DOI: 10.1080/21664250.2021.1932332.
6. Fujii, M., S. Takao, T. Yamaka, T. Akamatsu, Y. Fujita, M. Wakita, A. Yamamoto, and T. Ono (2021), Continuous monitoring and future projection of ocean warming, acidification, and deoxygenation on the subarctic coast of Hokkaido, Japan, Frontiers in Marine Science, 8, 590020, doi: 10.3389/fmars.2021.590020.
7. Shimahata, A., M. Farghali, and M. Fujii (2020), Factors influencing the willingness of dairy farmers to adopt biogas plants: A case study in Hokkaido, Japan. Sustainability, Sustainability, 12(18), 7809, https://doi.org/10.3390/su12187809.
8. Imamura, K., K. T. Takano, N. H. Kumagai, Y. Yoshida, H. Yamano, M. Fujii, T. Nakashizuka, and S. Managi (2020), Valuation of coral reefs in Japan: Willingness to pay for conservation and the effect of information, Ecosystem Services, https://doi.org/10.1016/j.ecoser.2020.101166.
9. Yasir Haya, L. O. M., and M. Fujii (2020), Assessment of coral reef ecosystem status in the Pangkajene and Kepulauan Regency, Spermonde Archipelago, Indonesia, using the rapid appraisal for fisheries and the analytic hierarchy process, Marine Policy, 118, 104028.
10. Endo, A., M. Yamada, Y. Miyashita, R. Sugimoto, A. Ishii, J. Nishijima, M. Fujii, T. Kato, H. Hamamoto, M. Kimura, T. Kumazawa, and J. Qi (2020), Dynamics of water–energy–food nexus methodology, methods, and tools, Current Opinion in Environmental Science & Health, 13, 46–60, DOI: 10.1016/j.coesh.2019.10.004.
11. Hong, H. T. C., R. Avtar, and M. Fujii (2019), Monitoring changes in land use and distribution of mangroves in the southeastern part of the Mekong River Delta, Vietnam, Tropical Ecology, 60, 552–565.
12. Zeng, J., T. Kumano, M. Fujii, S. Yamagata, M. Kamide, and H. Araki (2019), CO₂ emission and cost analysis in asparagus fusekomi forcing culture with wood pellet boiler, Japanese Journal of Farm Work Research, 54(1), 3-13.
13. Yasir Haya, L. O. M., and M. Fujii (2019), Assessing economic values of coral reefs in the Pangkajene and Kepulauan Regency, Spermonde Archipelago, Indonesia, Journal of Coastal Conservation, https://doi.org/10.1007/s11852-019-00700-3.
14. Ba, X., N. Kouchi, K. Watanabe, M. Nakaoka, and M. Fujii (2018), Material cycling in coastal waters and the role of the Kiritappu Wetland in Hamanaka, Hokkaido: An analysis using the surf clam (Pseudocardium sachalinense) as an environmental indicator, Marine Chemistry, 205, 81-89, DOI: 10.1016/j.marchem.2018.08.008.
15. Kumagai, N. H., J. García Molinos, H. Yamano, S. Takao, M. Fujii, and Y. Yamanaka (2018), Ocean currents and herbivory drive macroalgae-to-coral community shift under climate warming, Proc. Natl. Acad. Sci. USA, 115(36), 8990-8995, DOI: 10.1073/pnas.1716826115.
16. Gavrilyeva, T. N., A. Sugimoto, M. Fujii, R. Yamanaka, G. N. Pavlov, and D. A. Kirillin (2018), Sustainable development of universities: International and Russian practices]. Vysshee obrazovanie v Rossii (Higher Education in Russia), 27(7), 52-65. (in Russian with English abstract)
17. Fujii, M., and T. Sawadate (2018), Assessment of potential small hydropower generation: A case study in Otsuchi, Iwate Prefecture, Japan, In: Endo. A., and Oh, T. (eds.), The Water-Energy-Food Nexus: Human-Environmental Security in the Asia-Pacific Ring of Fire, Springer, 21-31.
18. 上野 洋路, 小埜 恒夫, 森岡 優志, 藤井 直紀, 藤井 賢彦, 轡田 邦夫, 原田 尚美 (2017), 海の出前授業: 日本海洋学会講師派遣事業, 沿岸海洋研究, 55(1), 65-70.
19. García Molinos, J, S. Takao, N. H. Kumagai, E. S. Poloczanska, M. T. Burrows, M. Fujii, and H. Yamano (2017), Improving the interpretability of climate landscape metrics: an ecological risk analysis of Japan’s Marine Protected Areas. Global Change Biology, 23, 4440-4452, doi: 10.1111/gcb.13665.
20. Yamada, M., J. Shoji, S. Ohsawa, T. Mishima, M. Hata, H. Honda, M. Fujii, and M. Taniguchi (2017), Hot spring drainage impact on fish communities around temperate estuaries in southwestern Japan, Journal of Hydrology: Regional Studies, 11, 69-83.
21. Fujii, M., S. Tanabe, M. Yamada, T. Mishima, T. Sawadate, and S. Ohsawa (2017), Assessment of the potential for developing mini/micro hydropower: A case study in Beppu City, Japan, Journal of Hydrology: Regional Studies, 11, 107-116. 
22. Yasir Haya, L. O. M., and M. Fujii (2017), Mapping the change of coral reefs using remote sensing and in situ measurements: a case study in Pangkajene and Kepulauan Regency, Spermonde Archipelago, Indonesia, Journal of Oceanography, 73(5), 623-645, doi:10.1007/s10872-017-0422-4.
23. Rospriandana, N. and M. Fujii (2017), Assessment of small hydropower potential in the Ciwidey subwatershed, Indonesia: a GIS and hydrological modeling approach, Hydrological Research Letters,  11(1), 6–11, doi: 10.3178/hrl.11.6.
24. Kumagai, N. H., H. Yamano, M. Fujii, Y. Yamanaka (2016), Habitat-forming seaweeds in Japan (fucoids and temperate kelps), Ecological Research, 31, 759–759, doi: 10.1007/s11284-016-1404-5.
25. Yara, Y., H. Yamano, M. Steinacher, M. Fujii, M. Vogt, N. Gruber, and Y. Yamanaka (2016), Potential future coral habitats around Japan depend strongly on anthropogenic CO₂ emissions, In: Nakano, S., T. Yahara, and T. Nakashizuka (eds.), Aquatic Biodiversity Conservation and Ecosystem Services, 41-56, Springer, Tokyo.
26. Orencio, P. M., A. Endo, M. Taniguchi, and M. Fujii (2016), Using thresholds of severity to threats to and the resilience of human systems in measuring security, Social Indicators Research, 129(3), 979-999, doi:10.1007/s11205-015-1152-x.
27. Takao, S., H. Yamano, K. Sugihara, N. H. Kumagai, M. Fujii, and Y. Yamanaka (2015), An improved estimation of the poleward expansion of coral habitats based on the interannual variation of sea surface temperatures, Coral Reefs, 34(4), 1125-1137, doi:10.1007/s00338-015-1347-2.
28. Fukuda, Y., and M. Fujii (2015), Biomass Resource Mapping and Potential Evaluation in Hokkaido, Japan, Journal of the Japan Institute of Energy, 94(9), 1057-1065, DOI: 10.3775/jie.94.1057.
29. Takao, S., N. H. Kumagai, H. Yamano, M. Fujii, and Y. Yamanaka (2015), Projecting the impacts of rising water temperatures on the distribution of seaweeds around Japan under multiple climate change scenarios, Ecology and Evolution, 5(1), 213-223, doi:10.1002/ece3.1358.
30. 柴野 良太, 藤井 賢彦, 山中 康裕, 山野 博哉, 高尾 信太郎 (2014), 北海道における沿岸水温環境とホタテガイ漁獲量の時空間変動解析, 水産海洋研究, 78(4), 259-267.
31. Yamano, H., C. Hongo, K. Sugihara, Y. Yara, Y. Nakao, and M. Fujii (2014), Current status of national coral databases in Japan: Dataset development, applications, and future directions, In: Nakano, S., T. Yahara, T. Nakashizuka (Eds.), Integrative Observations and Assessments, Springer, 65-81, DOI: 10.1007/978-4-431-54783-9_4.
32. Magdaong, E., H. Yamano, and M. Fujii (2014), Development of a large-scale, long-term coral cover and disturbance database in the Philippines, In: Nakano, S., T. Yahara, T. Nakashizuka (Eds.), Integrative Observations and Assessments, Springer, 83-109, DOI: 10.1007/978-4-431-54783-9_5.
33. Araki, H., S. Fujiwara, T. Jishi, M. Fujii, T. Yokota, and T. Nishida (2014). Winter production of green asparagus by using surplus heat from machinery room and used hot water from hotel’s spa. Acta Horticulturae, 1037, 155-162, DOI: 10.17660/ActaHortic.2014.1037.15.
34. Yara, Y., M. Fujii, H. Yamano and Y. Yamanaka (2014), Projected coral bleaching in response to future sea surface temperature rises and the uncertainties among climate models, Hydrobiologia, doi: 10.1007/s10750-014-1838-0.
35. Magdaong, E. T., M. Fujii, H. Yamano, W. Y. Licuanan, A. Maypa, W. L. Campos, A. C. Alcala, A. T. White, D. Apistar, and R. Martinez (2014), Long-term change in coral cover and the effectiveness of marine protected areas in the Philippines: a meta-analysis, Hydrobiologia, doi: 10.1007/s10750-013-1720-5.
36. Honjo, K., and M. Fujii (2014), Impacts of demographic, meteorological, and economic changes on household CO₂ emissions in the 47 prefectures of Japan, Regional Science Policy & Practice, 6(1), 13-31, doi:10.1111/rsp3.12013.
37. Orencio, P. M., and M. Fujii (2014), A spatiotemporal approach for determining disaster-risk potential based on damage consequences of multiple hazard events, Journal of Risk Research, 17(7), 815-836, doi:10.1080/13669877.2013.816334.
38. Orencio, P. M., and M. Fujii (2013b), A Localized Disaster-resilience Index to Assess Coastal Communities Based on an Analytical Hierarchy Process (AHP), International Journal of Disaster Risk Reduction, 3, 62-75.
39. Orencio, P. M., and M. Fujii (2013a), An index to determine vulnerability of communities developing a composite index for vulnerability of communities in a coastal zone: A case study of Baler, Aurora, Philippines, A Journal of the Human Environment (AMBIO), doi:10.1007/s13280-012-0331-0.
40. Yara, Y., M. Vogt, M. Fujii, H. Yamano, C. Hauri, M. Steinacher, N. Gruber, and Y. Yamanaka (2012), Ocean acidification limits temperature-induced poleward expansion of coral habitats around Japan, Biogeosciences, 9, 4955-4968, doi:10.5194/bg-9-4955-2012.
41. 藤原 沙弥香, 地子 立, 荒木 肇, 藤井 賢彦 (2012), 温泉地におけるCO₂排出量低減の可能性検討 －北海道・流山温泉と夕張温泉における未利用エネルギーの利用促進に向けたケーススタディ－, 日本LCA学会誌, 8(4), 356-369, DOI: 10.3370/lca.8.356.
42. 山田 健太, 藤井 賢彦, 荒木 肇 (2012), 大学キャンパスにおける有機性廃棄物の学内循環システムの導入可能性検討: 北海道大学をケーススタディとして, 日本LCA学会誌, 8(1), 45-54, DOI: 10.3370/lca.8.45.
43. Tanaka, A., M. Fujii, and T. Oishi (2012), Availability of an equation to equation to evaluate error by optical path discretization in radiative transfer computation based on the successive order of scattering method, Journal of Oceanography, 68(1), 215-218, DOI: 10.1007/s10872-011-0087-3.
44. Yara, Y., K. Oshima, M. Fujii, H. Yamano, Y. Yamanaka, and N. Okada (2011), Projection and uncertainty of the poleward range expansion of coral habitats in response to sea surface temperature warming: A multiple climate model study, Galaxea, 13(1), 11-20.
45. Lin, Y., M. Fujii, W. Peng (2011), Study on comparison of citizen’s environmental awareness among four cities in China and Japan, Management Science and Engineering, 5(3), 126-131, doi:10.3968/j.mse.1913035X20110503.315.
46. 藤井 賢彦, 山野 博哉 (2010), 『大森 (2010) 「中尾ら(2009)　日本のサンゴ被度データベースの作成と分析. 日本サンゴ礁学会誌 11: 109-129」に対するコメント』への回答, 日本サンゴ礁学会誌, 12, 53-57.
47. 屋良 由美子, 藤井 賢彦, 山中 康裕, 岡田 直資, 山野 博哉, 大島 和裕 (2009), 地球温暖化に伴う海水温上昇が日本近海のサンゴ分布及び健康度に及ぼす影響評価, 日本サンゴ礁学会誌, 11, 131-140, DOI: 10.3755/jcrs.11.131.
48. 中尾 有伸, 山野 博哉, 藤井 賢彦, 山中 康裕 (2009), 日本のサンゴ礁データベースの作成と分析, 日本サンゴ礁学会誌, 11, 109-129, DOI: 10.3755/jcrs.11.109.
49. Fujii, M., F. Chai, L. Shi, H. Y. Inoue, and M. Ishii (2009), Seasonal and interannual variability of oceanic carbon cycling in the western and central tropical-subtropical Pacific: A physical-biogeochemical modeling study, J. Oceanogr., 65(5), 689-701.
50. Fujii, M., and F. Chai (2009), Influences of initial plankton biomass and mixed-layer depths on the outcome of iron-fertilization experiments, Deep-Sea Res. Part II, 56(26), 2936-2947, DOI: 10.1016/j.dsr2.2009.07.007.
51. Kishi, M. J., K. Nakajima, M. Fujii, and T. Hashioka (2009), Environmental factors which affect growth of Japanese common squid, Tadarodes pacificus, analyzed by a bioenergetics model coupled with a lower trophic ecosystem model, J. Mar. Sys., 78(2), 278-287, DOI: 10.1016/j.jmarsys.2009.02.012.
52. Fujii, M., and Y. Yamanaka (2008), Effects of storms on primary productivity and air-sea CO₂ exchange, Biogeosciences, 5, 1189-1197.
53. 増田 良帆, 山中 康裕, 笹井 義一, 藤井 賢彦 (2008), 海洋大循環モデルによる年間5000万トン注入ケースのシミュレーション, 海洋理工学会誌, 14(1), 81-87.
54. Fujii, M., E. Boss, and F. Chai (2007b), The value of adding optics to ecosystem models: a case study, Biogeosciences, 4, 817-835.
55. Friedrichs, M. A. M., J. A. Dusenberry, L. A. Anderson, R. A. Armstrong, F. Chai, J. R. Christian, S. C. Doney, J. Dunne, M. Fujii, R. Hood, D. J. McGillicuddy Jr., J. K. Moore, M. Schartau, Y. H. Spitz, and J. D. Wiggert (2007), Assessment of skill and portability in regional marine biogeochemical models: Role of multiple planktonic groups, J. Geophys. Res., 112, C08001, doi:10.1029/2006JC003852.
56. Fujii, M., and F. Chai (2007a), Modeling carbon and silicon cycling in the equatorial Pacific, Deep-Sea Res. Part II, doi:10.1016/j.dsr2.2006.12.005.
57. Kishi, M. J., M. Kashiwai, D. M. Ware, B. A. Megrey, D. L. Eslinger, F. E. Werner, M. Aita-Noguchi, T. Azumaya, M. Fujii, S. Hashimoto, D. Huang, H. Iizumi, Y. Ishida, S. Kang, G. A. Kantakov, H. Kim, K. Komatsu, V. V. Navrotsky, S. L. Smith, K. Tadokoro, A. Tsuda, O. Yamamura, Y. Yamanaka, K. Yokouchi, N. Yoshie, J. Zhang, Y. I. Zuenko, and V. I. Zvalinsky (2007), NEMURO – a lower trophic level model for the North Pacific marine ecosystem, Ecological Modelling, 202(1-2), 12-25, doi:10.1016/j.ecolmodel.2006.08.021.
58. Fujii, M., Y. Yamanaka, Y. Nojiri, M. J. Kishi, and F. Chai (2007a), Comparison of seasonal characteristics in biogeochemistry among the subarctic North Pacific stations described with a NEMURO-based marine ecosystem model, Ecological Modelling, 202(1-2), 52-67, doi:10.1016/j.ecolmodel.2006.02.046.
59. Fujii, M., M. Ikeda, and Y. Yamanaka (2005b), Roles of biogeochemical processes in the carbon cycle using a simple coupled physical-biogeochemical model, J. Oceanogr., 61(5), 803-815.
60. Yoshie, N., M. Fujii, and Y. Yamanaka (2005), Ecosystem changes after the SEEDS iron fertilization in the western North Pacific simulated by a one-dimensional ecosystem model, Prog. Oceanogr., 64(2-4), 283-306, doi:10.1016/j.pocean.2005.02.010.
61. Fujii, M., N. Yoshie, Y. Yamanaka, and F. Chai (2005a), Simulated biogeochemical responses to iron enrichments in three high nutrient, low chlorophyll (HNLC) regions, Prog. Oceanogr., 64(2-4), 307-324, doi:10.1016/j.pocean.2005.02.017.
62. Fujii, M., and F. Chai (2005), Effects of biogenic silica dissolution on silicon cycling and export production, Geophys. Res. Lett., 32(5), L05617, doi:10.1029/2004GL022054.
63. Yamanaka, Y., N. Yoshie, M. Fujii, M. Aita-Noguti, and M. J. Kishi (2004), An ecosystem model coupled with Nitrogen-Silicon-Carbon cycles applied to Station A7 in the Northwestern Pacific, J. Oceanogr., 60(2), 227-241.
64. Fujii, M., Y. Nojiri, Y. Yamanaka, and M. J. Kishi (2002), A one-dimensional ecosystem model applied to time-series Station KNOT, Deep-Sea Res. Part II, 49, 5441-5461, DOI: 10.1016/S0967-0645(02)00207-2.
65. Fujii, M., M. Ikeda, and Y. Yamanaka (2000), Roles of physical processes in the carbon cycle using a simplified physical model, J. Oceanogr., 56(6), 655-666.