九州大学 研究者情報
論文一覧
高松 洋(たかまつ ひろし) データ更新日:2018.07.26

教授 /  工学研究院 機械工学部門 生体工学講座


原著論文
1. Hiroshi Takamatsu, Haidong Wang, Takanobu Fukunaga, Kosaku Kurata, Measurement of fluid thermal conductivity using a micro-beam MEMS sensor, International Journal of Heat and Mass Transfer, 10.1016/j.ijheatmasstransfer.2017.09.117, 117, 30-35, 2018.01, [URL], A new method for measuring thermal conductivities of gases and liquids was established by demonstrating the measurement of five kinds of liquid and air. It uses a sensor named “micro-beam sensor” that is a ∼10-μm-long free-standing platinum membrane suspended across a trench on a silicon substrate and heated in a sample by DC. This method is unique in that it is a steady-state measurement but free from the effect of natural convection owing to the micrometer size of the sensor. Improving the method for precisely determining the temperature of the sensor and modifying the device from those used in our previous feasibility study, we successfully measured the thermal conductivity ranging from ∼0.03 to ∼0.6 W/(m⋅K) within 4% error..
2. Kosaku Kurata, Junpei Matsushita, Atsushi Furuno, Junichi Fujino, Hiroshi Takamatsu, Assessment of thermal damage in total knee arthroplasty using an osteocyte injury model, Journal of Orthopaedic Research, 10.1002/jor.23600, 35, 12, 2799-2807, 2017.12, [URL], Polymethylmethacrylate bone cement has been widely used for the anchorage of artificial implants in various orthopedic surgeries. Although it is one of the most successful biomaterials in use, excess heat generation intrinsically causes thermal damage to bone cells adjacent to the bone cement. To estimate a risk of thermal injury, a response of bone cells to cement polymerization must be elucidated because of the occurrence of thermal damage. Thermal damage is affected not only by maximal temperature but also by exposure time, temperature history, and cell type. This study aimed at quantifying the thermal tolerance of bone cells for the development of a thermal injury model, and applying this model for the estimation of thermal damage during cement polymerization in total knee arthroplasty. Osteocytes, osteoblasts, and fibroblasts were respectively subjected to steady supraphysiological temperatures ranging from 45 to 50°C. Survival curves of each cell and temperatures were used to formulate the Arrhenius model. A three-dimensional heat conduction analysis for total knee arthroplasty was conducted using the finite element model based on serial CT images of human knee. A maximal temperature rise of 50°C was observed at the interface between the 3-mm thick cement and the tissue immediately beneath the tibial tray of the prosthesis. The probability of thermal damage to the osteocyte, which was calculated using the Arrhenius model, was negligible at a distance of at least 1 mm away from the cement–bone interface..
3. Mohammed Shurrab, Haidong Wang, Takanobu Fukunaga, Kosaku Kurata, Hiroshi Takamatsu, Feasibility of using apparent thermophysical properties to incorporate the effect of blood perfusion in estimation of temperature in tissues, Journal of Thermal Science and Technology, 10.1299/jtst.2017jtst0034, 12, 2, 2017.11, [URL], Estimation of temperature distribution in tissues and organs is critically important for treatments such as hyperthermia, radiofrequency ablation and cryosurgery which expose malignant tissue to extreme temperatures that are different from the physiological temperature. Commonly, the bioheat equation, instead of heat conduction equation, is used for estimation to incorporate the effect of blood perfusion, because the heat transfer in tissues is significantly affected by blood perfusion in addition to thermophysical properties of tissues. Nevertheless, in many cases, the rate of blood perfusion is not available for human tissues and organs. This study therefore aims to examine if we can use the normal heat conduction equation with apparent thermophysical properties to take the effect of blood perfusion into account. Feasibility was checked by comparing the results obtained from the heat conduction equation and the bioheat equation. The result indicated that the simulation with the apparent thermal conductivity or specific heat capacity does not agree well with the temperature distribution inside a tissue with blood perfusion. However, the apparent thermal conductivity was useful to estimate the size of growing ice ball produced during cryosurgery..
4. Kosaku Kurata, Takashi Yoshii, Yoshihiro Deguchi, Hiroshi Takamatsu, Raman microspectroscopic detection of thermal denaturation associated with irreversible electroporation, International Journal of Heat and Mass Transfer, 111, 163-170, 2017.08.
5. Shuto Yoshimatsu, Masahiro Yoshida, Kosaku Kurata, Hiroshi Takamatsu, Development of contact irreversible electroporation using a comb-shaped miniature electrode, Journal of Thermal Science and Technology, 10.1299/jtst.2017jtst0023, 12, 2, 2017.08, [URL], Irreversible electroporation (IRE) has been studied as a less invasive method for tumor treatment. Since the mechanism of the treatment is based on the fatal perforation of the cell membrane caused by an external electric field, a tumor can be ablated non-thermally if an appropriate electric field is selected. However, an electric field more than a few kV/cm is required to accomplish ablation. In this study, we aim to examine the feasibility of a comb-shaped miniature electrode for reducing the required voltage for IRE. The reduction of the applied voltage while maintaining the potential difference was realized by narrowing the gap between the electrodes. A 150-μm-wide miniature electrode with a 100-μm gap between its teeth was fabricated using photolithography. In the experiment, the electrode was contacted onto a tissue phantom consisting of fibroblasts cultured in agarose gel three-dimensionally. After the application of electric pulses, cell ablation depth was examined using fluorescent staining. The miniature electrode successfully ablated the cells at the surface of the tissue phantom by the application of 90 electric pulses at 100 V. The maximum and average ablation depth were 72.7 μm and 61.0 ± 11 μm, respectively, which was approximately 40 % of that estimated by the numerical analysis. Our study showed that the contact-IRE using a miniature electrode in the order of sub-millimeter does ablate the superficial cells of targeted tissues upon the application of electric pulses of less than 100 V; however, further studies are required to maximize the ablation depth under the constraint of limited applied voltage..
6. Wang H D, Takamatsu H, Zhang X, Width-dependent thermal conductivity of suspended single- layer graphene, Proceedings of 1st Asian Conference on Thermal Science (ACTS 2017), 2017.03.
7. Wang H D, Takahashi K, Takamatsu H, Zhang X, Highly sensitive charge mobility of suspended monolayer graphene, Proceedings of 6 th International Symposium on Micro and Nano Technology (ISMNT 2017), 2017.03.
8. Haidong Wang, Kosaku Kurata, Takanobu Fukunaga, Xing Zhang, Hiroshi Takamatsu, Width dependent intrinsic thermal conductivity of suspended monolayer graphene, International Journal of Heat and Mass Transfer, 105, 76-80, 2017.01.
9. Haidong Wang, Kosaku Kurata, Takanobu Fukunaga, Koji Takahashi, Xing Zhang, Hiroshi Takamatsu, Effect of nanohole defect on the thermal conductivity of free-standing single-layer graphene, Proceedings of 11th Asian Thermophysical Properties Conference (ATPC 2016), 2016.10.
10. Mohammed Shurrab, Haidong Wang, Noriaki Kubo, Takanobu Fukunaga, Kosaku Kurata, Hiroshi Takamatsu, The cooling performance of a cryoprobe: Establishing guidelines for the safety margins in cryosurgery, International Journal of Refrigeration, 67, 308-318, 2016.07.
11. Haidong Wang, Kosaku Kurata, Takanobu Fukunaga, Hiroki Ago, Hiroshi Takamatsu, Xing Zhang, Tatsuya Ikuta, Koji Takahashi, Takashi Nishiyama, Yasuyuki Takata, Simultaneous measurement of electrical and thermal conductivities of suspended monolayer graphene, Journal of Applied Physics, 119, 244306 (6 pages), 2016.06.
12. Haidong Wang, Kosaku Kurata, Takanobu Fukunaga, Hiroshi Takamatsu, Xing Zhang, Tatsuya Ikuta, Koji Takahashi, Takashi Nishiyama, Hiroki Ago, Yasuyuki Takata, A simple method for fabricating free-standing large area fluorinated single-layer graphene with size-tunable nanopores, Carbon, 99, 564-570, 2016.04.
13. Kazuhiro Nishimura, DONG HAI WANG, Takanobu Fukunaga, Kosaku Kurata, Hiroshi Takamatsu, Measurement of in-plane thermal and electrical conductivities of thin film using a micro-beam sensor: A feasibility study using gold film, International Journal of Heat and Mass Transfer, 95, 727-734, 2016.04, A new method was proposed for measuring the in-plane thermal conductivity of thin films using a free-standing “micro-beam” metallic sensor. The sensor is heated in a vacuum with a direct current to induce temperature rise, which is determined from the electrical resistance of the sensor. The method consists of two protocols: measurement of a bare sensor and that after deposition of a sample film on its top surface. Based on the principle that the temperature rises of the sensor with and without a deposited film is different from each other because of the difference in the in-plane thermal conductance, the thermal conductivity of the sample film is determined by comparing the measured temperature rise with that obtained by a numerical analysis. In the present study, measurement of a 20-nm thick gold film was demonstrated by fabricating two platinum sensors that have different widths. The measured thermal conductivities of the platinum sensor and the gold film were significantly smaller than those of bulk materials. The relation between the thermal conductivity and the electrical conductivity was also discussed..
14. Kosaku Kurata, Hiroshi Takamatsu, Medical application of intense electric pulses for sustainable health, AIP Conference Proceedings, 1717, 020002 (7 pages), 2016.03.
15. Mohammed Shurrab, Haidong Wang, Noriaki Kubo, Takanobu Fukunaga, Kosaku Kurata, Hiroshi Takamatsu, A Reference for Cryosurgery using Two Parallel Cryoprobes: Simulation and Experiment using a Tissue Phantom, 低温医学, 41, 2, 69-74, 2016.03.
16. Haidong Wang, Kosaku Kurata, Takanobu Fukunaga, Hiroshi Takamatsu, Xing Zhang, Tatsuya Ikuta, Koji Takahashi, Takashi Nishiyama, Hiroki Ago, Yasuyuki Takata, In-situ measurement of the heat transport in defect- engineered free-standing single-layer grapheme, Scientific Reports, 6, 21823, 2016.02.
17. H.D.Wang, X.Zhang, Takamatsu H, Ultraclean suspended monolayer graphene achieved by in situ current annealing, Nanotechnology, 28, 45706, 2016.01.
18. Alan Twomey, Kosaku Kurata, Hiroshi Takamatsu, Alptekin Aksan, Microheterogeneity in frozen protein solutions, International Journal of Pharmaceutics, 487, 91-100, 2015.04.
19. Hideto Hirahara, Yutaka Nagare, Alan Twomey, Kosaku Kurata, Takanobu Fukunaga, Alptekin Aksan, Hiroshi Takamatsu, Observation of ice-solute interaction in freezing of trehalose and albumin solutions by using confocal Raman microscope equipped with directional solidification stage, Proceedings of the 15th International Heat Transfer Conference, IHTC15-8933, 14, 2014.08.
20. Hiroshi Takamatsu, Kosaku Kurata, Engineering approach to irreversible electroporation, Proceedings of the 15th International Heat Transfer Conference, IHTC15-KN05, 18, 2014.08, 本論文では,著者が過去数年にわたって行って来た不可逆エレクトロポレーションに関する研究のレビューを行った.不可逆エレクトロポレーションとは高電圧パルスを組織に印加し,細胞膜のみを破壊する新しい治療法である.この治療法に関して,通電に起因した組織の温度上昇の検出とシミュレーションによる温度上昇の予測,電圧印加条件に依存した細胞壊死範囲の実験による特定とシミュレーションとの比較など,工学的な見地からの検討を行った..
21. Kosaku Kurata, Seiji Nomura, Hiroshi Takamatsu, Three-dimensional analysis of irreversible electroporation: Estimation of thermal and non-thermal damage, International Journal of Heat and Mass Transfer, 72, 66-74, 2014.05.
22. Gang Zhao, Hiroshi Takamatsu, Xiaoming He, The effect of solution nonideality on modeling transmembrane water transport and diffusion-limited intracellular ice formation during cryopreservation, Journal of Applied Physics, 115, 144701, 13, 2014.04.
23. Syamsul Hadi, Mamoru Nishitani, Agung Tri Wijayanta, Takanobu Fukunaga, Kosaku Kurata, Hiroshi Takamatsu, Contact measurement of thermal conductivity and thermal diffusivity of solid materials: Experimental validation of feasibility with a prototype sensor, International Journal of Heat and Mass Transfer, 10.1016/j.ijheatmasstransfer.2013.09.068, 69, 256-263, 2014.02, 新しい治療法である不可逆エレクトロポレーションを表在性の腫瘍に適用する為の基礎研究として,生体ファントムを用いた実験およびシミュレーションを行った..
24. Hiroshi Takamatsu, Takanobu Fukunaga, Yuki Tanaka, Kosaku Kurata, Koji Takahashi, Micro-beam sensor for detection of thermal conductivity of gases and liquids, Sensors and Actuators A, 10.1016/j.sna.2013.11.019, 206, 10-16, 2014.02, 本論文は,新しく提案したビーム型のMEMSセンサを用いて液体及び気体試料の熱伝導率を測定する方法に関するものである.このセンサを用いると,原理的にはわずか1マイクロリットルの試料の熱伝導率を1ミリ秒程度で簡単に測定できる.本論文では,実際にセンサを試作して,測定が可能であることを実証した..
25. 野村 征爾, 藏田 耕作, 高松 洋, 生体組織の不可逆エレクトロポレーションと熱的損傷発生のシミュレーション, 生体医工学, 51, 6, 357-365, 2013.12, 本論文は,新しい低侵襲治療法である非熱的不可逆エレクトロポレーションの数値解析結果を示したものである.電場および温度場の三次元数値解析を行って,細胞の壊死範囲および温度上昇による組織の熱的損傷を予測した..
26. Kosaku Kurata, Ryo Ueno, Masahiro Matsushita, Takanobu Fukunaga, Hiroshi Takamatsu, Experimental and Analytical Studies on Contact Irreversible Electroporation for Superficial Tumor Treatment, Journal of Biomechanical Science and Engineering, 8, 4, 306-318, 2013.12, 本論文は,新しい低侵襲治療法である非熱的不可逆エレクトロポレーションを表在組織に適用する為の実験的,解析的研究である.不可逆エレクトロポレーションは,組織に穿刺した電極間に高電圧パルスを印加して細胞膜のみを破壊する治療法であるが,本研究では穿刺電極を使わない接触式エレクトロポレーションを提案し,数値解析とともに三次元培養モデル組織を用いた実験によりその実現可能性を示した..
27. 高松 洋, 内田 悟, 安達 健二, 藤野 淳市, 上村 岳, クライオプローブまわりの模擬生体組織の凍結, 日本冷凍空調学会論文集, 30, 3, 221-230, 2013.09.
28. Alan Twomey, Rebekah Less, Kosaku Kurata, Hiroshi Takamatsu, Alptekin Aksan, In Situ Spectroscopic Quantification of Protein–Ice Interactions, The Journal of Physical Chemistry B, 117, 26, 7889-7897, 2013.06.
29. Kosaku Kurata, Takashi Yoshii, Satoru Uchida, Takanobu Fukunaga, Hiroshi Takamatsu, Visualization of electroporation-induced temperature rise using temperature-sensitive ink, International Journal of Heat and Mass Transfer, 10.1016/j.ijheatmasstransfer.2012.07.038, 55, 23-24, 7207-7212, 2012.11, 本論文は,不可逆エレクトロポレーションで生じる可能性のある組織の瞬間的な温度上昇を初めて実験的に捉えた研究である.高電圧パルス印加による温度上昇は数十マイクロ秒程度であるため,通常の温度測定法では測定不可能である.そこで,本研究では,感温性のインクを使って温度上昇を検知する方法を開発し,生体ファントムの温度上昇の測定に成功した..
30. Takashi Kono, Yasunori Ayukawa, Yasuko Moriyama, Kosaku Kurata, Hiroshi Takamatsu, Kiyoshi Koyano , The effect of low-magnitude, high-frequency vibration stimuli on the bone healing of rat incisor extraction socket, Journal of Biomechanical Engineering, 134.0, 9.0, 091001(6 pages), 2012.09.
31. Syamsul Hadi, Mamoru Nishitani, Agung Tri Wijayanta, Kosaku Kurata, Hiroshi Takamatsu, Measurement of Thermal Conductivity and Thermal Diffusivity of Solid Materials Using a Novel Stamp Sensor: A Feasibility Study with Numerical Analysis, Journal of Thermal Science and Technology, 7.0, 4.0, 536-548, 2012.08.
32. Kosaku Kurata, Masahiro Matsushita, Takashi Yoshii, Takanobu Fukunaga, Hiroshi Takamatsu, Effect of Irreversible Electroporation on Three-Dimensional Cell Culture Model, The 34th Annual International Conference of the IEEE EMBS12, 2012.08.
33. Syamsul Hadi, Mamoru Nishitani, Agung Tri Wijayanta, Kosaku Kurata, Hiroshi Takamatsu, Measurement of Thermal Conductivity and Thermal Diffusivity of Solid Materials Using a Novel Stamp Sensor: A Feasibility Study with Numerical Analysis, Journal of Thermal Science and Technology, 7.0, 4.0, 536-548, 2012.08.
34. Gang Zhao, Kosaku Kurata, Hiroshi Takamatsu, Measurement of membrane hydraulic conductivity of bovine carotid artery endothelial cells using a perfusion microscope , Cryo-Letters, 33.0, 3.0, 232-240, 2012.05.
35. K. Kurata, H. Takamatsu, Effect of Hyperthermal Treatment on the Viability of Bone-Derived Cells, Journal of Biomechanical Science and Engineering, 6.0, 2.0, 101-113, 2011.04.
36. S. Nomura, K. Kurata, H. Takamatsu, Effect of Three-Dimensional Electric Field and Heat Conduction to Electrodes on the Temperature Rise

During Irreversible Electroporation, Proc. The 8th ASME-JSME Thermal Engineering Joint Conference, AJTEC2011-44214, 1-10., 2011.03.
37. H. Takamatsu, T. Tanaka, Y. Furuya, S. Uchida, K. Kurata, K. Takahashi, Preliminary Study of the Measurement of Thermal Conductivity of Fluids with a Micro-Beam MEMS Sensor, Proc. 9th Asian Thermophysical Properties Conference, Paper No. 109047, 2010.10, 本論文は,微量流体試料の熱伝導率が測定できるMEMSセンサの開発を目的として行ったものである.そして,マイクロビームセンサと名付けた長さが10ミクロン程度の微細なセンサを加熱すると,数百マイクロ秒で定常熱伝導状態に達することを数値計算により見出した.そして,定常に達した後のセンサ温度に及ぼす試料の熱伝導率の影響を明らかにし,新しい熱伝導率センサが開発可能であることを示した..
38. H. Takamatsu, Biotransport in Freezing of Cells, Proc. National Thermofluid Seminar, 2010.08.
39. H. Takamatsu, K. Inada, S. Uchida, K. Takahashi, M. Fujii, Feasibility Study of a Novel Technique for Measurement of Liquid Thermal Conductivity with a Micro Beam Sensor, International Journal of Thermophysics, 31.0, 41734.0, 888-899, 2010.05.
40. H. Takamatsu, K. Inada, T. Tanaka, S. Uchida, K. Takahashi, M. Fujii, Feasibility Study of a Novel Technique for Measurement of Liquid Thermal Conductivity with a Micro Beam Sensor, Proc. 17th Symposium on Thermophysical Properties, 2009.06.
41. 稲田教介, 田中利幸, 内田悟, 高橋厚史, 藤井丕夫, 高松洋, マイクロビームセンサによる極微量液体の熱伝導率測定法に関する解析, 熱物性, 第23巻,第2号, 2009.05.
42. T. Yoshimori, H. Takamatsu, 3-D measurement of osmotic dehydration of isolated and adhered PC-3 cells, Cryobiology, Vol. 58, No. 1, pp.52-61, 2009.02.
43. 吉田敬介,安達健二,吉森崇志,内田悟,高松洋, インピーダンス計測による電解質水溶液の共晶凝固判別, 日本冷凍空調学会論文集, 25巻,2号,219-224, 2008.06.
44. H. Takamatsu, S. Uchida, T. Matsuda, In situ harvesting of adhered target cells using thermoresponsive substrate under a microscope: Principle and instrumentation, J. Biotechnology, Vol. 134, No. 3-4, 297-304, 2008.04.
45. 高松洋, 電解質の濃度変化による単離細胞の障害と凍結損傷, 低温生物工学会誌, 53巻1号,39-45, 2007.09.
46. H. Takamatsu, Freezing of Cells; Role of Ice and Solutes in Cell Damage, Proc. ASME-JSME 2007 Thermal Eng. and Summer Heat Transfer Conf. (CD-ROM), HT2007-32250, 1-10, 2007.07.
47. K. Yoshida, S. Uchida, H. Takamatsu, M. Fujii, Feasibility Study of Noninvasive Measurement of Thermal Conductivity and Thermal Diffusivity for Biological Materials, Proc. ASME-JSME 2007 Thermal Eng. and Summer Heat Transfer Conf. (CD-ROM), HT2007-32740, 1-6, 2007.07.
48. 内田悟,吉田敬介,高松洋,張興,藤井丕夫, 生体の熱伝導率,熱拡散率の非侵襲測定法(伝熱モデルと測定精度の検討), 日本機械学会論文集(B編), 72, 723, 2774-2779, 2006.11.
49. H. Takamatsu, S Uchida, T. Matsuda, A Method for In-Situ Targeting and Harvesting of Cultured Cells Under a Microscope, Proc. 2006 Int. Symp. Micro-Nanomechatronics and Human Science, 160-163, 2006.11.
50. 佐々木直栄,高松洋,山城光,植田茂樹,水田貴彦, 臭化リチウム水溶液による水蒸気の鉛直管内吸収, 銅と銅合金, 45, 1, 37-41, 2006.08.
51. H. Takamatsu, S. Zawlodzka, Contribution of Extracellular Ice Formation and the Solution Effects to the Freezing Injury of PC-3 Cells Suspended in NaCl Solutions, Cryobiology, 53, 1, 1-11, 2006.08.
52. 高松洋,Sylwia Zawlodzka,宮永武, 細胞の緩速凍結損傷に及ぼす細胞外氷晶形成と電解質濃縮の影響, 日本機械学会論文集(B編), 72, 717, 1342-1348, 2006.06.
53. 高松洋,山城光,井手悟,高田信夫,佐々木直栄, LiBr水溶液による鉛直管内水蒸気吸収と流下液膜への吸収解析, 日本冷凍空調学会論文集, 22, 3, 227-236, 2005.09.
54. S. Zawlodzka, H. Takamatsu, Osmotic Injury of PC-3 Cells by Hypertonic NaCl Solutions at Temperatures above 0°C, Cryobiology, 10.1016/j.cryobiol.2004.10.004, 50.0, 1.0, 50, 1, 58-70, 2005.02.
55. H. Takamatsu, R. Takeya, S. Naito, H. Sumimoto, On the Mechanism of Cell Lysis by Deformation, J. Biomech., 10.1016/j.jbiomech.2004.03.011, 38.0, 1.0, 38, 1, 117-124, 2005.01.
56. H. Takamatsu, Y. Komori, S. Zawlodzka, M. Fujii, Quantitative Examination of a Perfusion Microscope for the Study of Osmotic Response of Cells, J. Biomech. Eng., 10.1115/1.1784474, 126.0, 4.0, 126, 4, 402-409, 2004.08.
57. H. Honda, N. Takata, H. Takamatsu, J.S. Kim, K. Usami, Effect of Fin Geometry on Condensation of R407C in a Staggered Bundle of Horizontal Finned Tubes, J. Heat Transfer, 10.1151/1.1560153, 125.0, 4.0, 125, 653-660, 2003.08.
58. H. Takamatsu, H. Yamashiro, N. Takata, H. Honda, Vapor Absorption by LiBr Aqueous Solution in Vertical Smooth Tubes, Int. J. Refrig., 10.1016/S0140-7007(03)00038-0, 26.0, 6.0, 26, 659-666, 2003.07.
59. H. Honda, H. Takamatsu, J.J. Wei, Enhanced Boiling Heat Transfer from Silicon Chips with Micro-Pin Fins Immersed in FC-72, J. Enhanced Heat Transfer, 10.0, 2.0, 10, 2, 211-223, 2003.04.
60. H. Honda, J.J. Wei, H. Takamatsu, H. Yamashiro, Heat Transfer Characteristics of a Natural Circulation Liquid Cooling System for Electronic Components, Proc. 6th ASME/JSME Therm. Eng. Conf., TED-AJ03-122, 8.0, 2003.03.
61. H. Takamatsu, N. Kumagae, Survival of Biological Cells Deformed in a Narrow Gap, J. Biomech. Eng., 10.1115/1.1516197, 124.0, 6.0, 124, 6, 780-783, 2002.12.
62. 高松洋, 山城光, 高田信夫, 中山武, 本田博司, LiBr水溶液による鉛直平滑管内水蒸気吸収, 日本冷凍空調学会論文集, 19, 3, 211-221, 2002.10.
63. H. Honda, J.J. Wei, H. Takamatsu, Effect of Surface Microstructure on Boling Heat Transfer from Silicon Chips Immersed in FC-72, Therm. Sci. Eng., 10, 5, 9-17, 2002.09.
64. 高松洋, 川原智, 黒川壮志, 本田博司, 高濃度塩化ナトリウム水溶液による細胞の体積変化と損傷, 日本機械学会論文集(B編), 68, 672, 2320-2336, 2002.08.
65. 本田博司, 高松洋, 魏進家, マイクロピフィンを有するシリオンチップ上のFC-72の沸騰熱伝達におよぼすフィン寸法の影響, 日本機械学会論文集(B編), 68, 672, 2327-2332, 2002.08.
66. H. Honda, H. Takamatsu, J.J. Wei, Effect of the Size of Micro-Pin-Fin on Boiling Heat Transfer from Silicon Chips Immersed in FC-72, Proc. 12th Int. Heat Transfer Conf., 75-80, 2002.08.
67. 本田博司, 高松洋, 魏進家, マイクロピンフィンおよびサブミクロン粗さを有するシリコンチップ上のFC-72の沸騰熱伝達, 日本機械学会論文集(B編), 68, 666, 519-526, 2002.02.
68. H. Honda, N. Takata, H. Takamatsu, J. -S. Kim, K. Usami, Condensation of Downward-flowing HFC134a in a Staggered Bundle of Horizontal Finned Tubes: Effect of Fin Geometry, Int. J. Refrigeration, 10.1016/S0140-7007(01)00023-8, 25.0, 1.0, 25, 3-10, 2002.01.
69. H. Takamatsu, H. Yamashiro, N. Takata, H. Honda, K. Kasatsugu, Absorption of Water Vapor by LiBr Aqueous Solution in a Vertical Smooth Tube, Proc. IIR Conf. Commission B1, Thermopyhsical Properties and Transfer Processes of New Refrigerants, 2001.10.
70. H. Honda, H. Takamatsu, J. J. Wei, Effect of the Size of Micro-Pin-Fin on Boiling Heat Transfer from Silicon Chips Immersed in FC-72, Therm. Sci. Eng., 9, 4, 27-28, 2001.06.
71. H. Takamatsu, N. Kumagae, B. Rubinsky, The Effect of Temperature on the Viability of Deformed Cells, ASME HTD-VOl. 368/BED-Vol. 47, Advances in Heat and Mass Transfer in Biotechnology 2000, 55-58, 2000.11.
72. H. Honda, N. Takata, H. Takamatsu, J. -S. Kim, K. Usami, Effect of Fin Geometry on Condensation of R134a in a Staggered Bundle of Horizontal Finned Tubes, Proc. 4th JSME/KSME Therm. Eng. Conf., 1, 1-10, 2000.10.
73. H. Honda, H. Yamashiro, H. Takamatsu, Stability of Vapor Film in Subcooled Film Boiling on a Sphere, Proc. 34th Nat. Heat Transfer Conf., 41649.0, 2000.08.
74. 本田博司, 高田信夫, 高松洋, 金正植, 宇佐見啓一郎, 冷媒R134aの千鳥配列フィン付き管群内凝縮におよぼすフィン形状の影響, 日本冷凍空調学会論文集, 17, 4, 481-487, 2000.05.
75. 本田博司, 高田信夫, 高松洋, 金正植, 宇佐見啓一郎, 非共沸混合冷媒R407Cの千鳥配列フィン付き管群内凝縮に及ぼすフィン形状の影響, 日本冷凍空調学会論文集, 17, 4, 501-509, 2000.05.
76. H. Honda, H. Takamatsu, N. Takata, Experimental Measurements for Condensation of Downward-Flowing R123/R134a in a Staggered Bundle of Horizontal Low-Finned Tubes with Four Geometries, Int. J. Refrig., 10.1016/S0140-7007(99)00026-2, 22.0, 8.0, 22, 8, 615-624, 1999.12.
77. H. Takamatsu, M. Fujii, H. Honda, H. Uchiyama, Stability of Annular Liquid Film in Microgravity, Microgravity Science and Technology, 12.0, 1.0, 12, 1, 2-8, 1999.12.
78. 高松洋, B. Rubinsky, 圧縮変形を受ける細胞の生残率の測定, 日本機械学会論文集(B編), 65, 639, 3821-3824, 1999.11.
79. H. Takamatsu, B. Rubinsky, Viability of Deformed Cells, Cryobiology, 10.1006/cryo.1999.2207, 39.0, 3.0, 39, 3, 243-251, 1999.11.
80. 本田博司, 山城光, 高松洋, 球まわりの過冷膜沸騰における蒸気膜の安定性, Therm. Sci. Eng., 7, 5, 1-10, 1999.09.
81. 本田博司, 山城光, 高松洋, 田中一雄, 水平細線の浸漬急速冷却過程における極小熱流束点におよぼす蒸気挙動の影響, 日本機械学会論文集(B編), 65, 636, 2806-2813, 1999.08.
82. H. Honda, H. Takamatsu, N. Takata, M. Tawaraya, Condensation of Downward-Flowing R407C in a Staggered Bundle of Horizontal Low-Finned Tubes, Proc. 1st Int. Conf. Engineering Thermophysics(ICET '99), 404-411, 1999.08.
83. H. Kubo, H. Takamatsu, H. Honda, Effect of Size and Number Density of Micro-Reentrant Cavities on Boiling Heat Transfer from a Silicon Chip Immersed in Degassed and Gas-Dissolved FC-72, J. Enhanced Heat Transfer, 6, 2-4, 151-160, 1999.05.
84. H. Honda, H. Takamatsu, N. Takata, Condensation of Downward-Flowing Zeotropic Mixture HCFC-123/HFC-134a on a Staggered Bundle of Horizontal Low-Finned Tubes, J. Heat Transfer, 10.1115/1.2825993, 121.0, 2.0, 121, 2, 405-412, 1999.05.
85. H. Honda, H. Yamashiro, H. Takamatsu, Effect of the Behavior of Generated Vapor on the Minimum-Heat-Flux Point During Rapid Quenching of a Thin Horizontal Wire, Proc. 5th ASME/JSME Therm. Eng. Conf., AJTE99-6366, 1999.03.
86. K.-S. Cho, H. Honda, H. Takamatsu, H. Nakahama, Effect of Water Temperature on the Cooling Characteristics and Non-Crystallinity of FeSi7.5B15 Wires Rapidly Solidified by the In-Rotating-Water Spinning Method, Proc. 5th ASME/JSME Therm. Eng. Conf., AJTE99-6466, 1999.03.
87. 本田博司, 高松洋, 山城光, 水平円筒まわりの強制対流過冷膜沸騰における蒸気膜の安定性(周期的熱伝導を考慮した解析), 日本機械学会論文集(B編), 64, 628, 4166-4171, 1998.12.
88. 曺奎常, 高松洋, 本田博司, 回転水中紡糸法で作成されたFeSi7.5B15(at%)合金細線の非晶質度に及ぼす水温の影響, 日本金属学会誌, 62, 12, 1157-1162, 1998.12.
89. S.-R. Tian, H. Takamatsu, H. Honda, Experimental Study on the Immersion Cooling of an Upward-Facing Multichip Module with an Opposing Condensing Surface, Heat Transfer Jpn. Res., 27, 7, 497-508, 1998.11.
90. H. Honda, H. Takamatsu, N. Takata, Effect of Fin Geometry on Condensation of Downward-Flowing R123/R134a in a Staggered Bundle of Horizontal Low-Finned, Proc. Eurotherm Seminar 62, 456-465, 1998.11.
91. 曺奎常, 高松洋, 本田博司, 森永健次, 回転水中紡糸法で製造されたFe77.5Si7.5B15(at%)合金細線の非晶質度に及ぼす紡糸条件の影響, 日本金属学会誌, 62.0, 1998.08.
92. H. Honda, H. Takamatsu, H. Yamashiro, Stability of Vapor Film in Subcooled Forced-Convection Film Boiling on a Horizontal Cylinder, Proc. 11th Int. Heat Transfer Conf., 2, 297-302, 1998.08.
93. 本田博司, 高松洋, 高田信夫, 非共沸混合冷媒HCFC-123/HFC-134aの千鳥配列ローフィン管群における凝縮-フィン形状の影響-, 日本冷凍空調学会論文集, 15, 2, 175-184, 1998.07.
94. 高松洋, 久保秀雄, 本田博司, リエントラント型人工くぼみを有する模擬チップの浸漬沸騰冷却, 日本機械学会論文集(B編), 64, 621, 1426-1432, 1998.05.
95. 高松洋, 藤井丕夫, 本田博司, 内山弘規, 微小重力下における環状液膜の安定性, 日本機械学会論文集(B編), 64, 619, 904-909, 1998.03.
96. 本田博司, 高松洋, 高田信夫, 非共沸混合冷媒HCFC-123/HFC-134aの千鳥配列ローフィン管群における凝縮, 日本冷凍空調学会論文集, 15, 1, 63-71, 1998.03.
97. 曺奎常, 高松洋, 本田博司, 回転水中紡糸法で製造される金属細線の形態に及ぼす紡糸条件の影響, 日本金属学会誌, 62, 2, 189-196, 1998.03.
98. H. Yamashiro, H. Takamatsu, H. Honda, Enhancement of Cooling Rate During Rapid Quenching of a Thin Wire by Ultrasonic Vibration, Heat Transfer Jpn. Res., 27, 1, 16-30, 1998.02.
99. H. Yamashiro, H. Takamatsu, H. Honda, Effect of Ultrasonic Vibration on Transient Boiling Heat Transfer During Rapid Quenching of a Thin Wire in Water, J. Heat Transfer, 10.1115/1.2830055, 120.0, 1.0, 120, 1, 282-286, 1998.02.
100. K.-S. Cho, H. Takamatsu, H. Honda, Effect of Spinning Condition on the Cooling Characteristics and Shape of FeSi77.5B15 Wires Rapidly Solidified by the In-Rotating-Water Spinning Method, Heat Transfer Jpn. Res., 27, 1, 31-42, 1998.02.

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