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‹ÆуŠƒXƒg

Refereed articles:

  1. åM“à—F—C, ‘åΉël, “Bú±—CŽ÷. “n•ÓW¶, 2026, ’n‰º…—¬‰º‚É‚¨‚¯‚é“€“y’ŒŒ‹‡Žž‚̉·“x‹““®‚ÉŠÖ‚·‚錟“¢\“™‰·ü‹““®‚É’…–Ú‚µ‚½•ÂÇ”»’è‚̉”\«\, ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, in press
  2. Shun Kikuchi, Hirotaka Saito, Masato Oishi, Kunio Watanabe, Yusuke Yabuchi, 2026, Determining representative length in analytical model for artificial ground freezing: A mumerical study, Cold Regions Scienc and Technology, 245, 104842, https://doi.org/10.1016/j.coldregions.2026.104842
  3. Ying Zhao, Ce Zheng, Alexander Gelfan, Kunio Watanabe, Haojie Liu,Stephanie Wright, Xiaolong Wu, William Quinton, Yi Wang, Shuhua Yi, Yongyong Zhang, Yujie Shi, Wentao Jiao, 2026, Frozen soil hydrological processes and their effects: A review and synthesis, Reviews of Geophysics, Reviews of Geophysics, 64, e2024RG000839. https://doi.org/10.1029/2024RG000839.
  4. Nobuhito Sekiya, Ayaka Mae, Mchuno Alfred Peter, Maiko Goto, Hinata Kato, Shunsuke Ichikawa, Kunio Watanabe, 2025, Soil microbes and organic fertilizer efficiency are associated with rice field topography, Scientific Reports, 15, 249390; https://doi.org/10.1038/s41598-025-09111-x
  5. Nobuhito Sekiya, Ayaka Mae, Mchuno Alfred Peter, Beno Kiwale, Anton, Tasuku Eigen, Saki Yamayoshi, Masaru Sakai, Kunio Watanabe, Takaharu Kameoka, 2024, Sustainable nitrogen management in rice farming: spatial patterns of nitrogen availability and implications for community-level practices, Sustainability, 16(22), 9880; https://doi.org/10.3390/su16229880
  6. ²“¡i‹àŽqj‚Ì‚¼‚Ý, ”Ñ“‡Žœ—T, ‰ª“‡Œ«Ž¡, ŠÖ’JMl, “n•ÓW¶, 2024, UAS ƒŠƒ‚[ƒgƒZƒ“ƒVƒ“ƒO‚É‚æ‚é…“c“y뉻Šw«‚Ì„’踓x‚ɃsƒNƒZƒ‹’Šo”͈͂ƎB‰e‚“x‚ª—^‚¦‚é‰e‹¿, “yë‚Ì•¨—«, 158, 29-42
  7. Kenta Suzuki and Kunio Watanabe, 2023, Observation of ice lensing in directionally frozen soil using a hyperspectral camera, Proceedings of International Symposium on Ground Freezing, 41-47
  8. Nozomi Kaneko Sato, Takeshi Tsuji, Yoshihiro Iijima, Nobuhito Sekiya and Kunio Watanabe, 2023, Predicting rice lodging risk from the distribution of available nitrogen in soil using UAS images in a paddy field, Sensors, 23, 6466, doi.org/10.3390/s23146466
  9. “¿–{‰ÆN, œAZ–Lˆê, âˆäŸ, ¼˜e~Žq, ‰Á“¡çq, “n•ÓW¶, aŒûŸ, Îì—m•½, 2022, •úŽËü‹³ˆç‚Ì‚½‚߂̃AƒvƒŠƒP[ƒVƒ‡ƒ“ŠJ”­‚Æ‚»‚ÌŽÀ‘H—á, “d‹CŠw‰ï˜_•¶ŽA, 142(7), 300-306. doi:10.1541/ieejfms.142.300.
  10. ‰œ“c—Á‘¾, “n•ÓW¶, 2021, “yë…•ª—Ê‚ªˆÙ‚Ȃ镃{ƒN“y‚Ì“€Œ‹‰ß’ö‚É‚¨‚¯‚é”MˆÚ“®ƒƒJƒjƒYƒ€, ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, 89(1), I_173-I_180, doi:10.11408/jsidre.89.I_173
  11. Kazuyuki Saito, Kunio Watanabe, Shigenori Haginoya, Kazuo Takeda, Tetsuo Sueyoshi, Tomoyoshi Hirota, Masaru Mizoguchi, Koichiro Harada, Hiromasa Hosaka, Masato Kimura and Hironori Yabuki, 2020, Database for ground temperature and freezing depth in Japan, Polar Data Journal, 4, 83-96.
  12. •“¡—RŽq, “°ŽR‹ML, ’†¼^‹I, “n•ÓW¶, 2019, ö”­‰ß’ö‚É‚ ‚镃{ƒN“y’†‚É‚¨‚¯‚éɉ»‚𔺂¤’‚‘f‚Ì‹““®‰ðÍ‚ÆATP—Ê‘ª’è, ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, 309, ‡T_281-‡T_288
  13. ’·“c—F—¢Œb, ‘Š”nŒ[, –ØMÆ, “n•ÓW¶, 2019, ‘Ñ|•â‹­“y•Ç‚ÌŒðŠ·‚Ö‚Ì’n”Õ“€Œ‹H–@‚Ì“K—p, “yë‚Ì•¨—«, 143, 17-23.
  14. “n•ÓW¶, ’†¼^‹I, ‘[—L‹I, •“¡—RŽq, 2019, •s–O˜aZ“§‰ß’ö‚É‚ ‚éˆÙ‚Ȃ鉷“x‚Ì•ƒ{ƒN“y’†‚̃Aƒ“ƒ‚ƒjƒA‘Ô’‚‘f‚Ìɉ», ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, 308, I_1-I_8
  15. Kunio Watanabe and Yurie Osada, 2017, Simultaneous measurement of unfrozen water content and hydraulic conductivity of partially frozen soil near 0‹C, Cold Regions Science and Technologyl, 142, 79-84, doi: 10.1016/j.coldregions.2017.08.002
  16. “Bú±—CŽ÷, “n•ÓW¶, 2017, “yë“€Œ‹‘w‚Ì—Z‰ð‚É‚Æ‚à‚È‚¤“y’†‚Ì…•ªˆÚ“®, ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, 305(85-2).I_191-I_198
  17. •“¡—RŽq, ŒE“c—L^, ‹ËŽR’¼·, “n•ÓW¶, 2017, •Þê‚É‚¨‚¯‚é“yë…•ª—Ê‚Æ“d‹C“`“±—¦‚̘A‘±ŠÏ‘ª‚Ì‚½‚ß‚Ì5TEƒZƒ“ƒT[‚̊ȈՂȌ´ˆÊ’uƒLƒƒƒŠƒuƒŒ[ƒVƒ‡ƒ“, “yë‚Ì•¨—«, 137, 3-9.
  18. Kunio Watanabe and Yuki Kugisaki, 2017, Effect of macropores on soil freezing and thawing with infiltration, Hydrological Processes, 31, 270-278, doi: 10.1002/hyp.10939
  19. Chiemi Iba, Yoko Taniguchi, Keigo Koizumi, Kunio. Watanabe, Katsuhiko. Sano, Chunze Piao, Mizuho Yoshioka, 2016, Environmental monitoring and surface treatment tests for conservation of the rock hewn church of Uzumlu, cappadocia, Hughes, J., & Howind, T. (Eds.), Science and Art: A Future for Stone: Proceedings of the 13th International Congress on the Deterioration and Conservation of Stone, Volume 2, 1145-1152, Paisley: University of the West of Scotland. [PDF]
  20. Kunio Watanabe and Yurie Osada, 2016, Comparison of hydraulic conductivity in frozen saturated and unfrozen unsaturated soils, Vadose Zone Journal, doi: 10.2136/vzj2015.11.0154
  21. •“¡—RŽq, “n•ÓW¶, ŽR–{´m, ‘q“‡‰hˆê, 2015, 5TEƒZƒ“ƒT[‚Å‘ª’肵‚½“yë…•ª—ʂ̊ȈՕⳂƓd‹C“`“±—¦‚ÌŒŸØ, ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, 296, I-9-I-17..
  22. “€“y•ª‰È‰ï, 2014, “€“y‚Ì’mŽ¯-lH“€“y•Ç‚Ì‹Zp-, á•X, 76(2), 179-192.
  23. Barret Kurylyk and Kunio Watanabe, 2013, Review: The mathematical representation of freezing and thawing processes in variably-saturated, non-deformable soils, Advances in Water Resources, 60, 160-177doi:10.1016/j.advwatres.2013.07.016
  24. “n•ÓW¶, ˜a‹C•üŒÈC2013, “€Œ‹‰ß’ö‚É‚ ‚é•s–O˜a»’†‚Ì…•ªˆÚ“®‚Æ“§…ŒW”‚É—nŽ¿ˆÚ“®‚ª‹y‚Ú‚·‰e‹¿, á•X, 75(5), 253-261. [PDF]
  25. “n•ÓW¶, ’·“c—F—¢Œb, âˆäŸ, 2013, …•ª‹z’E’…‘ª’è‘•’u"AquaLab VSA"‚ð—p‚¢‚½’á…•ª—̈æ‚Ì…•ª•ÛŽ‹Èü‚Ì‘ª’è, “yë‚Ì•¨—«, 124, 43-49. [PDF] .
  26. •“¡—RŽq, ‰Á“¡ŠóŽ}, “n•ÓW¶, 2013, ö”­‰ß’ö‚É‚ ‚é“y’†‚ÌŽ_‰»ŠÒŒ³“dˆÊ‚̕ω», ”_‹Æ”_‘ºHŠw‰ï˜_•¶W, 284, 23-29.
  27. ŽRŒûŒå, “n•ÓW¶, Έä‹g”V, 2012, Ïá“à•”‚Ì…•ªˆÚ“®‚ÉŠÖ‚·‚éŽÀŒ±“IŒ¤‹†, “ú–{…•¶‰ÈŠw‰ïŽ, 42(3), 89-99.
  28. Kunio Watanabe, Tetsuya Kito, Shuhui Dun, Joan Q. Wu, R. Cory Greer and Markus Flury, 2013, Water infiltration into a frozen soil with simultaneous melting of the frozen layer, Vadose Zone Journal, 12, doi:10.2136/vzj2011.0188.
  29. Kunio Watanabe, Megumi Takeuchi, Yurie Osada and Kazumasa Ibata. 2012, Micro chilled-mirror hygrometer for measuring water potential in relatively dry and partially frozen soils. Soil Science Society of American Journal, 76, 1938-1945, doi:10.2136/sssaj2012.0070.
  30. Satoru Yamaguchi, Kunio Watanabe, Takafumi Katsushima, Atsushi Sato, and Toshiro Kumakura, 2012, Dependence of the water retention curve of snow on snow characteristics, Annals of Glaciology, 53(61), 6-12, doi:10.3189/2012AoG61A001.
  31. Satoshi Akagawa, Go Iwahana, Kunio Watanabe, Evgeny M. Chuvilin and Vladimir A. Istomin, 2012, Improvement of pulse NMR technology for determination of unfrozen water content in frozen soils, In Proceedings of 10th international conferenc on Permafrost, 21-26.[PDF]
  32. Kunio Watanabe, Tetusya Kito, Tomomi Wake, Masaru Sakai, 2011, Freezing experiments on unsaturated sand, loam and silt loam, Annals of Glaciology, 52(58), 37-43[PDF].
  33. “n•ÓW¶, ‹I“¡“N–î, âˆäŸ, ŽæoL•v, 2010, “€Œ‹–Ê‹ß–T‚Ì•s“€…—ʕω»‚ÉŠî‚­“€“y‚Ì…•ª“Á«‹Èü‚Æ•s–O˜a“§…ŒW”‚ÌŒŸ“¢, “yë‚Ì•¨—«, 116, 9-18.[PDF]
  34. ŽæoL•v, “n•ÓW¶, ’†ìˆºŽq, 2010, “y’†‚Ö‚Ì…‚ÌZ@4. ¬‘w“y, “yë‚Ì•¨—«, 116, 27-35.[PDF]
  35. ŽæoL•v, “n•ÓW¶, ‹vs—Y‘å, âˆäŸ, 2010, “y’†‚Ö‚Ì…‚ÌZ@3. Green and Amptƒ‚ƒfƒ‹, “yë‚Ì•¨—«, 115, 51-60.[PDF]
  36. “n•ÓW¶, ‘åX—z‰î, ˜a‹C•üŒÈ, âˆäŸ, 2010, ƒT[ƒ‚TDR‚É‚æ‚é“€“y‚Ì•s“€…•ª—ÊE”M“`“±—¦‚Ì“¯Žž‘ª’è , á•X,72(3), 157-168.
  37. ŽæoL•v, “n•ÓW¶, Xú±‘åŽ÷, 2010, “y’†‚Ö‚Ì…‚ÌZ@2. ‰Šú…•ª—Ê‚Ì‹y‚Ú‚·‰e‹¿, “yë‚Ì•¨—«, 114, 71-80.[PDF]
  38. ŽæoL•v, “n•ÓW¶, âˆäŸ, 2009, “y’†‚Ö‚Ì…‚ÌZ@1. ƒtƒ‰ƒbƒNƒX‹«ŠE‚ƈ³—Í‹«ŠEðŒ, “yë‚Ì•¨—«, 113, 31-41.[PDF]
  39. Kunio Watanabe and Tomomi Wake, 2009, Measurement of unfrozen water content and relative permittivity of frozen unsaturated soil using NMR and TDR, Cold Regions Science and Technology, 59(1), pp. 34-41 doi:10.1016/J.coldregions.2009.05.011.
  40. Kunio Watanabe and Markus Flury, 2008, Capillary bundle model of hydraulic conductivity for frozen soil, Water Resour. Res., 44, W12402, .doi:10.1029/2008WR007012.
  41. Kunio Watanabe and Misako Ito, 2008, In situ observation of the distribution and activity of microorganisms in frozen soil, Cold Regions Science and Technology,54, 1-6, [doi:10.1016/j.coldregions.2007.12.004]
  42. Kunio Watanabe and Tomomi Wake, 2008, Hydraulic Conductivity of Frozen Unsaturated Soil, In Proceedings of 9th International Conference on Permafrost, 147-152.[PDF]
  43. “n•ÓW¶, ŽæoL•v, âˆäŸEJiri Simunek, 2007, “€Œ‹‚𔺂¤“y’†‚Ì…•ªE”ME—nŽ¿ˆÚ“®ƒ‚ƒfƒ‹, “yë‚Ì•¨—«, 106, 21-32..[PDF]
  44. Kunio Watanabe, Yokokawa Kosuke and Muto Yoshiko, 2006, Observation of frost heave of THF clathrate hydrate on porous glass powder,In Cold Regions Engineering 2006; Current practices in cold regions engineering; proceedings of the 13th international conference (ed. Davies, Michael et al.), Proceedings of the International Symposium on Cold Regions Engineering, 13, 10 p. [PDF]
  45. “n•ÓW¶, ‰¡ìŒö—º, •“¡—RŽq, 2004, ƒKƒ‰ƒX•²‘Ì’†‚ÌTHFƒNƒ‰ƒXƒŒ[ƒgƒnƒCƒhƒŒ[ƒg‚Ì“€ãŒ»Û, “yë‚Ì•¨—«, 96, 83-88. [PDF]
  46. •“¡—RŽq, “n•ÓW¶, V¯•j, 2004, Œ¸ˆ³‚ªŠîŽ¿“Y‰ÁŒã‚Ì’c—±‚Ì‘S’Y‘f—Ê‚É—^‚¦‚é‰e‹¿, “yë‚Ì•¨—«, 96, 65-70. [PDF]
  47. “n•ÓW¶, ’†¼Œ’ˆê, 2003, ŒuŒõxü•ªŒõ•ªÍ‚ð—p‚¢‚½“€Œ‹‰ß’ö‚É‚ ‚éƒKƒ‰ƒX•²‘Ì’†‚̃Jƒhƒ~ƒEƒ€”Z“x•ª•z‚ÌŠÏŽ@, ”_‹Æ“y–ØŠw‰ï˜_•¶W, 228, 99-104.
  48. Kunio Watanabe, Hideki Kiyosawa, Kazunari Fukumura, Tadataka Ezaki and Masaru Mizoguchi,2003, Spatial and temporal variation of thaw depth in Siberian tundra near Tiksi, In Proceedings of 8th international conferenc on Permafrost, 1211-1216. [PDF]
  49. Kunio Watanabe and Masaru Mizoguchi, 2002, Amount of unfrozen water in frozen porous media saturated with solution, Cold Regions Science and Technology, 34 (2), 103-110. [PDF]
  50. Kunio Watanabe, 2002, Relationship between growth rate and supercooling in the formation of ice lenses in a glass powder, Journal of Crystal Growth, 237-239Part3, 2194-1298. [PDF]
  51. Kunio Watanabe, Yoshiko Muto and Masaru Mizoguchi, 2001, Water and solute distributions near an ice lens in a glass-powder medium saturated with sodium chloride solution under unidirectional freezing, Crystal Growth and Design, 1, pp. 207-211. [PDF]
  52. •“¡—RŽq, “n•ÓW¶, Îè•Žu, aŒûŸ, 2001, ƒKƒ‰ƒX‘½EŽ¿‘Ì’†‚̃AƒCƒXƒŒƒ“ƒY‚ÌŠÏŽ@@-ƒAƒCƒXƒŒƒ“ƒY‚̬’·‚ÆŠÜ…”ä‚ɂ‚¢‚Ä-, á•X, 63, 3-9.[PDF]
  53. Kunio Watanabe and Masaru Mizoguchi, 2000, Ice configuration near a growing ice lens in a freezing porous medium consisting of micro glass particles, Journal of Crystal Growth, 213, pp. 145-140. [PDF]
  54. “n•ÓW¶, aŒûŸ, ´àVGŽ÷, ™Z‹Ê—T“ñ, 2000, ƒVƒxƒŠƒA‚̃cƒ“ƒhƒ‰‚É‚¨‚¯‚銈“®‘w“yë‚Ì‘wˆÊ‚Æ•¨—“I«Ž¿, …•¶E…Ž‘Œ¹Šw‰ïŽ, 13, 9-16.
  55. Kunio Watanabe, Yoshiko Muto and Masaru Mizoguchi, 2000, A model for the formation of ice lenses in an unconfined, water-saturated, porous medium consisting of spherical particles, Ground Freezing 2000 ed. J-F Thimus, pp. 55-60. [PDF(1),PDF(2)]
  56. “n•ÓW¶, •“¡—RŽq, aŒûŸ, 1999, ƒKƒ‰ƒX•²—±‘Ì’†‚Ì‘wó•X¶¬ƒ‚ƒfƒ‹, á•X, 61, 207-214.[PDF]
  57. •“¡—RŽq, “n•ÓW¶, Îè•Žu, aŒûŸ, 1998, ƒKƒ‰ƒXƒr[ƒY’†‚É‚¨‚¯‚éƒAƒCƒXƒŒƒ“ƒYŒ`¬‰ß’ö‚ÌŒ°”÷‹¾ŠÏŽ@, ”_‹Æ“y–ØŠw‰ï˜_•¶W, 194, 97-103.
  58. Yoshiko Mutou, Kunio Watanabe, Takeshi Ishizaki, Masaru Mizoguchi, 1998, Microscopic observation of ice lensing and frost heaves in glass beads , In Proceedings of 7th International Conference on Permafrost, ed. A. G. Lewkowiez and M. Allard, 783-787. [PDF]
  59. Kunio Watanabe, Masaru Mizoguchi, Takeshi Ishizaki and Masami Fukuda, 1997, Experimental study on microstructure near freezing front during soil freezing, Ground Freezing 97, ed. S. Knutsson, pp. 187-192. [PDF(1), PDF(2)]
  60. “n•ÓW¶, aŒûŸ, Îè•Žu, 1997, “€Œ‹‰ß’ö‚É‚¨‚¯‚é“y‚Ì“€Œ‹–Ê‹ß–T‚Ì”÷Ž‹“I\‘¢‚ɂ‚¢‚Ä‚ÌŽÀŒ±Œ¤‹†, ”_‹Æ“y–ØŠw‰ï˜_•¶W, 191, 51-58.

Book chapters:

  1. ƒhƒ‚¦‚à‚ñ”ŽŽm‚Æ’‡ŠÔ‚½‚¿, 2019, ƒhƒ‚¦‚à‚ñ”ŽŽm‚̃ƒNƒƒN‹³Žºu“y‚Á‚Ä‚Ó‚µ‚¬IHv, “Œ•û’ÊMŽÐ, ISBNF978-4-924508-27-9
  2. “ú–{á•XŠw‰ï ŠÄC@‚‹´C•½E“n•Ó‹»ˆŸ •Ò’˜, 2016, á‚Æ•X‚Ì‹^–â60@‚Ý‚ñ‚È‚ª’m‚肽‚¢ƒVƒŠ[ƒY2, ¬ŽR“°‘“X, ISBN978-4-425-51421-2
  3. “ú–{á•XŠw‰ï, 2014, V”Å@á•XŽ«“T, ŒÃ¡‘‰@, ISBN4-7722-4173-6
  4. “n•ÓW¶, 2008, “€Œ‹E—Z‰ð‰ß’ö‚É‚æ‚鑽EŽ¿‘Ì’†‚Ì…•ªE—nŽ¿ˆÚ“®, ‘½E‘̸̂–§§Œä‚Æ‹@”\¥•¨«•]‰¿, pp.399-407, Science&Technology, ISBN978-4-903413-34-1
  5. ƒEƒCƒŠƒAƒ€EƒWƒ…ƒŠ[,ƒƒo[ƒgEƒz[ƒgƒ“’˜,ŽæoL•vŠÄ–ó,ˆäãŒõO,’·—TK,¼‘º‘ñ,”ò—˜Žk,“n•ÓW¶–ó, 2006, “y땨—Šw@-“y’†‚Ì…E”MEƒKƒXE‰»Šw•¨Ž¿ˆÚ“®‚ÌŠî‘b‚Ɖž—p-, ’z’n‘ŠÙCISBN4-8067-1324-4


ƒvƒƒV[ƒfƒBƒ“ƒOƒXE‰ðà‘¼:

  1. “n•ÓW¶, 2023, •s–O˜a“€“y‚Ì“§…‹@\ , ’n”ÕHŠw‰ïŽ, 71(7), 6-9.
  2. “n•ÓW¶, 2021, Ïá’†‚Ì…•ªˆÚ“®‰ðÍ‚Æ“y땨—ƒ‚ƒfƒ‹@\ ŠÔŒ„\‘¢‚ªŒˆ’肯‚鑽EŽ¿‘Ì‚Ì•Û…«‚ƈړ®“Á« \ , á•X, 83(6), 547-554.
  3. ŽæoL•v, “n•ÓW¶, 2020, ŠK‘w“I‚È’c—±\‘¢‚ª¶‚Ýo‚·“y‚Ì•Û…‚Æ•¨Ž¿ˆÚ“®“Á«, •²‘Ì‹Zp, 12(12), 942-947.
  4. œAZ–Lˆê, “¿–{‰ÆN, âˆäŸ, ¼˜e~Žq, ‰Á“¡çq, “n•ÓW¶, ‰–àVms, aŒûŸ, 2020, •úŽËü‹³ˆç‚Ì‚½‚ß‚ÌŽq‚Ç‚àŒü‚¯ƒfƒWƒ^ƒ‹ŠG–{ƒAƒvƒŠƒP[ƒVƒ‡ƒ“, …“y‚Ì’m, 88(1), 19-22.
  5. œAZ–Lˆê, _’·—B, “¿–{‰ÆN, ¼˜e~Žq, âˆäŸ, ‰Á“¡çq, “n•ÓW¶, aŒûŸ, 2019, ŽOdŒ§Žl“úŽsŽs‚É‚¨‚¯‚é•úŽËü‹³ˆçƒAƒEƒgƒŠ[ƒ`Šˆ“®‚Ì“WŠJ, …“y‚Ì’m, 87(11), 31-34.
  6. ¼˜e~Žq, “¿–{‰ÆN, âˆäŸ, ‰Á“¡çq, œAZ–Lˆê, “n•ÓW¶, ‰–àVms, aŒûŸ, 2018, •œ‹»”_ŠwŽ–‹Æ‚É‚¨‚¯‚é•Ÿ“‡Œ¤”ÑŠÚ‘º‚ł̈‚è‘ÌŒ±EŒ»êŒ©Šw‰ð, …“y‚Ì’m, 86(1), 31-34.
  7. œAZ–Lˆê, âˆäŸ, _’·—B, “¿–{‰ÆN, ¼˜e~Žq, ‰Á“¡çq, “n•ÓW¶, aŒûŸ, 2017, uŽl“úŽsŒöŠQ‚Ɗ‹«–¢—ˆŠÙv‚É‚¨‚¯‚é•Ÿ“‡Œ§ŠO‰‚Ì•œ‹»”_ŠwŽÀŒ±uÀ, …“y‚Ì’m85(11), 1037-1040.
  8. Yoko Tanicuthi, Keigo Koizumi, Chiemi Iba, Kunio Watanabe, Katsuhiko Sano, Piao Chunze, Hatic Temur, Ayca Basturkmen, Ugur Yalcinkaya, Mustafa Toptepe, 2016, Scientific research for conservation of rock-hewn church, Uzumlu (Cappadocia) in 2015: Chapel of niketas the stylite in Red Valley, 38th International Symposium of Excavations, Surveys and Archaeometry, pp.525-544.
  9. M. Yoshioka, C. Iba, K. Watanabe, Y. Taniguchi, K. Koizumi, K. Sano, C. Piao, 2016, Effects of water repellent on frost damage in outer walls of rock-hewn churchs in Cappadocia, Turkey, Proc. the CESBP Central European Symposium on Building Physics and BauSIM 2016, 277-284.
  10. ‰Á“¡çq, âˆäŸ, ¼˜e~Žq, “¿–{‰ÆN, œAZ–Lˆê, “n•ÓW¶, ‰–àVms, aŒûŸ, 2016, •Ÿ“‡Œ§“ଊwZ‚É‚¨‚¯‚é•œ‹»”_Šwo‘OŽö‹Æ, …“y‚Ì’m, 84(6), 479-482.
  11. “n•ÓW¶, •ÄŽR–¾’j, ’|’J•q, ’·“c—F—¢Œb, ”ºr˜a, 2015, Xüƒ}ƒCƒNƒCT‚ð—p‚¢‚½•s–O˜a“y’†‚ÌŠÔŒ„\‘¢‚Æ…•ª•ÛŽŒ`‘Ô‚ÌŠÏŽ@, Photon Factory Activity Report 2014 #32, B-356 [PDF]
  12. Kunio Watanabe, 2015, Monitoring and estimation of water and heat flows in the rocks at the base of ?z?ml? church, Scientific studies on conservation for Uzumlu Church and its wall paintins in Cappadocia, Turkey, Vol. 1: Annual report on the activities in 2014.[PDF]
  13. Ä“¡˜a”VC––‹g“N—YC“n•ÓW¶C•“cˆê•vC2013, “ú–{‘“à’n‰·E“€Œ‹[ƒf[ƒ^‚ÌŽûWE®”õ, á•X, 75(5), 291-296. [PDF]
  14. “n•ÓW¶, ’Ö{—zˆê, ‹I“¡“N–î, 2012, “€Œ‹‘w‚ðŽ‚“y’†‚Ö‚ÌÉŽ_‰–—n‰t‚ÌZC“yë…•ªƒ[ƒNƒVƒ‡ƒbƒv˜_•¶W, 67-72.[PDF]
  15. Ä“¡˜a”V, ––‹g“N—Y, “n•ÓW¶, •“cˆê•v, 2011, “ú–{‘“à‚Ì’n‰·E“€Œ‹[ƒf[ƒ^‚ÌŽûWE®”õ‚ɂ‚¢‚ÄC“yë…•ªƒ[ƒNƒVƒ‡ƒbƒv˜_•¶W, 61-63.
  16. “n•ÓW¶, 2009, “€“y’†‚Å“€‚ç‚È‚¢…‚Ì‘ª’è–@‚ƃ‚ƒfƒ‹C“yë…•ªƒ[ƒNƒVƒ‡ƒbƒv˜_•¶W, pp 21.1 - 21.8..[PDF][µ‘Ò˜_•¶]
  17. Kunio Watanabe, 2008, Water and heat flow in a directionally frozen silty soil. In: H. Saito, M. Sakai, N. Toride and J. Simunek (eds.), Proc. of The Third HYDRUS Workshop, June 28, 2008, Tokyo University of Agriculture and Technology, Tokyo, Japan, ISBN 978-4-9901192-5-6, pp. 15-22, 2008.[PDF]
  18. “n•ÓW¶, 2004, ˆê•ûŒü“€Œ‹–@‚É‚æ‚é“yëò‰», Materials Integration, 17, 39-44. [PDF]
  19. “n•ÓW¶, 2003, “€ãŒ»Û‚Æ‚»‚Ì—˜—p‚ɂ‚¢‚Ä, Ž‘—¿F“€Œ‹‚Æ“€ãŒ»Û‚Ì’n”Õ‰ü—Ç‚Ö‚Ì“K—p‚ÉŠÖ‚·‚éƒ[ƒNƒVƒ‡ƒbƒv, pp 13-18.
  20. Kunio Watanabe, Tadataka Ezaki, Kazunari Fukumura, Masaru Mizoguchi and Hideki Kiyosawa, 2001, Variability of thaw depth depending on surface micro-undulation and vegitation cover in the Siberian tundra, In Proceedings of the 5th International Study Conference on GEWEX in Asia and GAME, vol. 3, Nagoya, Japan, pp. 632-636. [PDF]
  21. “n•ÓW¶, 2000, ƒAƒCƒXƒŒƒ“ƒY‚̬’·–Ê‹ß–T‚Ì”÷Ž‹“IŠÏŽ@‚Æ‚»‚̶¬ƒ‚ƒfƒ‹, “yë‚Ì•¨—«, 84, 49-56.[PDF]
  22. Tadataka Ezaki, Kunio Watanabe, Masaru Mizoguchi and Hideki Kiyosawa, 2000, Estimating the spatial distribution of thaw depth in the Siberian tundra near Tiksi from ground surface images relating with micro undulation and vegetation, Activity Report of GAME-Siberia 1999, pp 23-24. [PDF]
  23. Yohiko Muto, Kunio Watanabe, Masaru Mizoguchi and Takeshi Ishizaki, 1999, Experimental study of frost heaving using glass particles. EOS, Transactions, AGU 80 (American Geophysical Union Fall Meeting, San Francisco, USA) p F427.
  24. Kunio Watanabe, Masaru Mizoguchi, Norihumi Satou and Yuji Kodama , 1999, Classification of active layer soil along a line in Siberian wetland. In Proceedings of 3rd International Scientific Conference on the Global Energy and Water Cycle, Beijing, China, pp. 300-301. [PDF]
  25. Masaru Mizoguchi, Kunio Watanabe, Kazunari Fukumura and Hideki Kiyosawa, 1999, Spatial distribution of active layer on a hillslope in Siberian tundra. In Proceedings of 3rd International Scientific Conference on the Global Energy and Water Cycle, Beijing, China, 302-303. [PDF]
  26. Kunio Watanabe and Masaru Mizoguchi, 1999, Pit observations of active layer in tundra wetland near Tiksi, Siberia, Activity Report of GAME-Siberia 1998, pp 37-42. [PDF]
  27. Masaru Mizoguchi, Kunio Watanabe, Kazunari Fukumura and Hideki Kiyosawa, 1999, Spatial distribution of active layer on a hillslope in Siberian tundra, Activity Report of GAME-Siberia 1998, pp 35-36. [PDF]
  28. Kunio Watanabe, Masaru Mizoguchi, Norifumi Satou and Yuji Kodama, 1998, Physical properties of active layer soil in Siberian wetland, Activity Report of GAME-Siberia 1996-1997, pp 60-62. [PDF]
  29. Masaru Mizoguchi, Kunio Watanabe and Yuji Kodama, 1998, Spatial variation of active layer thickness in Siberian tundra, Activity Report of GAME-Siberia 1996-1997, pp 54-56.
  30. Kunio Watanabe, 1996, Microscopic observation of ice crystal growth in clay. In Proceedings of Sapporo Conference on the Chemistry of Clays and Clay Minerals, Sapporo, Japan, p. 149.
  31. Masaru Mizoguchi and Kunio Watanabe, 1994, A study on behavior of unfrozen interlayer water in clay by MD method, Agronomy Abstracts 248, Seattle, USA.


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