1. 1.Watanabe T., Matsunaka T., Nakamura T., Nishimura M., Izuya Y., Minami M., Nara Watanabe F., Kakegawa T., Wang J.B., Zhu L.P. (2010) Last glacial-Holocine geochronology of sedimentcores from a high-altitude Tibetan lake based on AMC C-14 dating of plant fossils: Implications for paleoenvironmental reconstructions.  Chemical Geology, vol. 277, pp. 21-29.
   

2. 2.Naraoka H., Uehara T., Hanada S. and Kakegawa T.(2010) δ13C- δ D distribution of lipid biomarkers in a bacterial mat from a hot spring in Miyagi Prefecture, NE Japan. Organic Geochemistry. Vo.41., p398-403.（査読あり）
   

3. 3.Kato S., Takano Y., Kakegawa T. et al. (2010) Biogeography and biodiversity in sulfide structures of active and inactive vents at deep-sea hydrothermal fields of the southern Mariana Trough.  Applied and environmental microbiology, vol. 76, p2968-2979.（査読あり）
   

4. 4.Takahashi S, Kaiho K., Oba M.and Kakegawa T. (2010) A smooth negative shift of organic carbon isotope ratios at an end-Permian mass extinction horizon in central pelagic Panthalassa.  Paleogeography, Paleoclimatpology and Paleoecology, vol.292, p532-539. （査読あり）
   

5. 5.山田亮一、吉田武義、掛川武、奈良郁子、小川泰正(2010)東北地方北部の金属鉱床に随伴する高インジウム鉱石の形成条件、資源地質、６０巻、p.153-164.
   

6. 6.掛川武 (2010)古生物学辞典、分担執筆、朝倉書店pp.576(査読無し)
   

7. 7.Kato S., Yanagawa K., Sunamura M., Takano Y., Ishibashi J., Kakegawa T. et al (2009) Abundance of zetaproteobacteria within crustal fluids in back-arc hydrothermal fields of the Southern Mariana Trough.  Environmental Microbiology. Vol. 11, pp.3210-3222.
   

8. 8.Kato S., Hara K., Kasai H., Teramura T. Sunamura M., Ishibashi J-I., Kakegawa T., Yamanaka T., Kimura H., Marumo K., Urabe T., Yamagishi A. (2009) Spatial distribution, diversity and composition of bacterial communities in sub-seafloor fluids at a deep-sea hydrothermal field of the Suiyo Seamount. Deep Sea Research Part 1, vol.56.pp.1844-1855.
   

9. 9.Watanabe T., Nakamura T., Watanabe Nara F., Kakegawa T., Nishimura M., Shimokawara M., Matsunaka T., Senda R., Kawai T. (2009) A new age model for the sediment cores from Academician ridge (Lake Baikal) based on high-time-ressolution AMS 14C data sets over the last 30 kyr: Paleoclimatic and environmental implications, Earth Planetary Science Letter. Vol.286., pp.347-354.
   

10. 10.Kato S., Kobayashi C., Kakegawa T., Yamagishi A. (2009) Microbial communities in iron-silica rich microbial mats at deep-sea hydrothermal fields of the Southern Mariana Trough, vol.10, Environmental Microbiology, vol.11.pp.2094-2111.
    

11. 11.Watanabe T., Nakamura T., Nara F., Kakegawa T. and other 6 (2009) High-time resolution AMS 14C data sets for lake Baikal and Lake Hovsgol sediment cores: Changes in radiocarbon age and sedimentation rates during the transition from the last glacial to the Holocene.  Quaternary International. Vol.205., pp.12-20.
    

12. 12.Furukawa Y., Sekine T., Oba M., Kakegawa T. and Nakazawa H. (2009) Biomolecule formation by oceanic impacts on early Earth, Nature geoscience, vol.2, 62-66.
    

13. 13.Mizota, C., Doi, H., Kikuchi E., Shikano S., Kakegawa T., Yurlova N. and Yurlov A.K. (2008) Stable isotope characterization of fluids from the Lake Chany complex, western Siberia, Russian Federation.  Applied Geochemistry. Vol.24., 319-327.
    

14. 14.Kakegawa T., Utsumi M, . Marumo K. (2008) Geochemistry of Sulfide Chimneys and Basement Pillow Lavas at the Southern Mariana Trough (12.550N–12.580N) Resource Geology, vol.58, 249-266.
    

15. 15.Yamanaka T., Mizota C., Serisawa K., Kakegawa T. and Other 4 (2008) Stable isotopic characterization of carbon, nitrogen and sulfur uptake of Acharax japonica from central Japan. Plankton Benthos Research. Vol.3, 36-41.
    

16. 16.Ando A., Kaiho K., Kawahata H., Kakegawa T. (2008) Timing and magnitude of early Aptian extreme warming: Unraveling primary d18O variation in indurated pelagic carbonates at Deep Sea Drilling Project Site 463, Central Pacific Ocean. Paleogeo..Paleoclim. Paleoecol., vol. 260. 463-476.
    

17. 17.Furukawa Y., Nakazawa H., Sekine T. and Kakegawa T. (2007) Formation of ultrafine particles from impact-generated supercritical water. Earth Planetary Science Letter. 258. 543-549.
    

18. 18.Ohara S., Kakegawa T. and Nakazawa H. (2007) Pressure effects on the abiotic polymerization of glycine. Origin of Life and Evolution of Biosphere, 37. 215-223.
    

19. 19.Ando A. and Kakegawa T. (2007) Carbon isotope records of terrestrial organic matter and occurrence of plantonic foraminifera from the Albian stage of Hokkaido, Japan: Ocean - atmosphere delta C-13 trends and chronostratigraphic implications. Paleos 22, 417-432.
    

20. 20.Gorjan P., Kaiho K., Kakegawa T., Niitsuma S., Chen Z.Q., Kajiwara Y. and Nicora A. (2007) Paleoredox, biotic and sulfur-isotopic chages associated with the end-Permian mass extinction in the western Tethys.  Chemical Geology 244. 483-492.
    

21. 21.Coetzee L.L., Beukes N.J., Gutzmer J. and Kakegawa T. (2006) Links of organic carbon cycling and burial to depositional depth gradients and establishment of a snowball Earth at 2.3 Ga. Evidence from the Timeball Hill Formation, Transvaal Supergroup, S. Africa. S. African J. of Geol. 109, 109-122.
    

22. 22.Ohmoto H., Watanabe Y., Yamaguchi K., Naraoka, H., Haruna M., Kakegawa T., Hayshi K., and Kato Y. (2006) Chemical and biological evolution of early Earth: Constraints from banded iron-formations. Geological Society of America Special Paper 198. 291-331.
    

23. 23.Ando A., Kawahata H. and Kakegawa T. (2006) Sr/Ca ratios as indicators of varying modes of pelagic carbonate diagenesis in the ooze, chalk and limestone realms. Sediment. Geol. 191, 37-53.
    

24. 24.Kakegawa T. and Nanri H. (2006) Sulfur and carbon isotope analyses of 2.7 Ga stromatolites, cherts and sandstones in the Jeerinah Form., West. Australia. Precam. Res. 148, 115-124.
    

25. 25.Hara K., Kakegawa T., Yamashiro K., Maruyama A., Ishibashi J.I., Marumo K., Urabe T., Yamagishi A. (2005) Analyses of the archaeal sub-sefloor community  at Suiyo Seamount on the Izu-Bonin Arc.  Advances in Space Research. vol. 35. 1634-1642.
    

26. 26.Nakazawa H, Sekine T., Kakegawa T., Nakazawa S. (2005) High yield shock synthesis of ammonia from iron, water and nitrogen available on the early Earth. Earth Planet. Sci. Let. 235. 356-360.
    

27. 27.掛川武・野田雅一・丸茂克美 (2005) 水曜海山海底熱水域の地下地質構造と硫化物硫黄同位体組成との関係.　海の科学.　14巻. 221-235.
    

28. 28.掛川武 (2004)　27~21億年にかけて見いだされた異常な有機炭素同位体組成と初期生命進化. 岩石鉱物科学 vol.33, 141-145.
    

29. 29.Mori K., Kakegawa T., Higashi Y., Nakamura K., Maruyama A. and Hanada S. (2004) Oceanithermus desulfurans sp noy, a novel thermophilic sulfur-reducing bacterium isolated from a sulfide chimney in Suiyo Seamount. Int. J. System Evol. Microbio. 54,1561 -1566.
    

30. 30.Mori K., Kim H., Kakegawa T., Hanada S.(2003) A novel lineage of sulfate-reducing microorganisms: Thermodesulfobiaceae fam. nov., Thermodesulfobium narugense, gen. nov., sp. nov., a new thermophilic isolate from a hot spring., Extremophiles 7, 283-290.
    

31. 31.Ando A., Kakegawa T., Takashima R., Saito T (2003) Stratigraphic carbon isotope fluctuations of detrital woody materials during the Aptian  Stage in Hokkaido, Japan: Comprehensive d13C data from four sections of the Ashibetsu area. J. Asian Earth Sci. 21, 835-847.
    

32. 32.掛川武 (2003) 初期地球環境下での微生物進化.　日本惑星科学会誌 12. 14-18.
    

33. 33.掛川武 (2003) 太古代海洋における硫酸還元菌の活動と生息環境.地学雑誌, 112, 218-225.
    

34. 34.Ando A., Kakegawa T., Takashima R. Saito T (2002) New perspective on Aptian carbon isotope stratigraphy: Data from d13C records of terrestrial organic matter, Geology. 30, 227-230.
    

35. 35. Kakegawa T. , M. Noda and H. Nanri (2002) Geochemical Cycles of Bio-essential elements on the early Earth and their relationships to origin of life. Resource Geol., vol. 52. pp. 83-89.
    

36. 36.Kakegawa T.(2001): Activities of early life in the Archean oceans: influence from submarine hydrothermal activities. In“Geochemistry and Origin of Life”, Univ. Acad. Press, 50-63.
    

37. 37.Kakegawa T. (2000) Biological activities and evolution of life during early stage of the Earth history: Constraints from the stable isotope records.  Viva Origino. vol. 28, 191-208.
    

38. 38.Kakegawa T., Y. Kasahara, K. Hayashi and H. Ohmoto (1999a) Sulfur and carbon isotope analyses of the 2.7 Ga Jeerinah Formation, Fortescue Group, Australia, Geochem. Jour. vol. 34,　121-133.
    

39. 39.Kakegawa T. and H. Ohmoto (1999b) Sulfur isotope evidence for the origin of 3.4 and 3.1 Ga pyrite at the Princeton gold mine, Barberton greenstone belt, South Africa. Precam. Res. 96. 209-224.
    

40. 40.Kakegawa T., H. Kawai and H. Ohmoto (1998) Origins of pyrites in  the 2.5 Ga Mt.McRae Shale, the Hamersley district, Western Australia. Geochim. Cosmochimica Acta 62, 3205-3220.
    

41. 41.H. Ohmoto, Kakegawa T. and D. Lowe (1993) 3.4-billion-year-old biogenic pyrites from Barberton, South Africa: Sulfur isotope evidence. Science, 262, 555-557.
    

著書

1. 掛川武 (2009) 古生物学事典、朝倉書店 (分担執筆)

2. 伊藤絹子・掛川武 (2008) 河川汽水域を利用する魚類の食物源 ”安定同位体スコープで覗く海洋生物の生態” 恒星社厚生閣pp.70-84.

3. 大谷栄治・掛川武 (2005)　地球・生命ーその起源と進化,　共立出版. pp.196.

その他（紀要、ニュースレター）

1.掛川武(2009) 最初の地球の海に降り注ぎ込まれた鉄が生命を生んだ. 岩波「科学」10月号

2.掛川武 (2009) 生命の起源：地球惑星科学の新しい問題　日本地球惑星科学連合ニュースレター vol.5.５月号

3.掛川武 (2008) 第４回日独先端科学シンポジウム：新しい伝統の予感　          学術月報 vol.61. 59-61.

4. 掛川武 (2006) 初期地球環境と微生物活動の痕跡　遺伝 20,180-183.

5. 掛川武 (2004) グリーンランド・イスア地域の岩石に刻まれた初期地球の姿. 地質ニュース 596, 60-65.

6. 遠藤一佳、南澤究、掛川武、犬伏和之(2004)微生物学と地球科学のわかちがたい関係岩波「科学」vol74., pp.166-169.

7. 掛川武（2003）最古の岩石が秘める生命起源へのヒント．化学 58, 7，30-31.

特許

1. 関根利守, 中沢弘基, 中沢暁, 掛川武, 古川善博, 大原祥平 (2009) アミノ酸の合成方法.　 特許番号4288332号

  招待講演

1.　掛川武 (2010) 海底熱水活動域は生命起源と初期進化の場であったか？生命の起源と進化学会、函館

1. Ishida A., Kakegawa T. amd Oba M. (2008) Contrast compositions of minerals, kerogens and lipid-biomarkers in 1.9 Ga shallow- and deep-water sedimentary rocks of the Gunflint Formation, Canada. Goldschmidt Conference, Vancouver.

2. 掛川武 (2008) Dynamics of the Earth made the first life.日本地質学会, 秋田

3. 掛川武 (2008) 38-30億年前の海洋性堆積岩に記録された初期生物圏発達史:微少領域安定同位体分析による制約.地球化学会, 東京

4. 掛川武 (2006) 初期地球環境と微生物活動の痕跡:百花争乱 日本進化学会年会，8/30-31東京.

5. Kakegawa,T, (2005) Significant interaction between biosphere and crustal materials on the early Earth : possible production of pre-biotic materials and evolution of the early crusts. First Japanese-German Frontiers of Science Symposium, JSPS, Mainz, Jan 27-30.

6. Kakegawa T. (2003) Establishment of Phosphorous Cycle in Early Archean Oceans.  Goldschmidt Conference, Kurashiki, Japan, Sep. 7-12.

7. Kakegawa T. (2002) Subvent Hydrothermal Processes at the Suiyo Submarine Volcano, Japan: Constraints from Sulfur Isotope Compositions of Sulfides and Sulfates. American Geophysical Union Ocean Science Meeting. April 7th.

8. Kakegawa T.（2001）Influence of submarine hydrothermal activities onto the Archean ocean chemistry and ecosystem. American Chemical Society. San Diego. 04.07

9. 9.Kakegawa T. (1999) Do Micro-analyses of sulphur isotopes of pyrite in Precambrian sedimentary rocks suggest evaporitic Precambrian oceans? The University of Western Australia, Special Short Course“Precambrian Sediment-Hosted Metal Deposits” Perth, Australia, Aug. 2nd to 3rd.
   

集中講義

２０１０年１２月：九州大学

２００８年１１月：大阪大学

２００７年１１月：大阪市立大学

２００４年２月：静岡大学

２００２年１１月：筑波大学