| 1. |
Yu-ki Taninouchi, Toru H. Okabe, Trends of Technological Development of Platinum Group Metal Recycling: Solubilization and Physical Concentration Processes, Materials Transactions, 10.2320/matertrans.mt-m2022150, Vol.64, No.3, pp.627-637, 2023.03. |
| 2. |
谷ノ内 勇樹, 中野博昭, 最近の研究トピックス 九州大学大学院工学研究院材料工学部門 冶金物理化学講座 材料電気化学研究室, 環境資源工学, Vol.69, No.3, pp.170-173, 2023.03. |
| 3. |
谷ノ内 勇樹, 九州大学での夢と挑戦 ~最高のマテリアルは、、、~, 金属, Vol.92, No.12, pp.1238-1242, 2022.12. |
| 4. |
谷ノ内 勇樹, シリーズ「金属素描」No. 25 亜鉛(Zinc), まてりあ, Vol.61, No.11, p.723, 2022.11. |
| 5. |
谷ノ内 勇樹, 岡部 徹, 白金族金属リサイクルの現状と新規濃縮分離技術の開発, 表面技術, Vol.73, No.6, pp.276-282, 2022.06. |
| 6. |
谷ノ内 勇樹, 岡部 徹, 特集「貴金属のリサイクル関連技術の最前線II」によせて, 日本金属学会誌, 10.2320/jinstmet.jpr2021901, Vol.85, No.8, p.273, 2021.08. |
| 7. |
谷ノ内 勇樹, 岡部 徹, 白金族金属リサイクル技術の開発動向:易溶化プロセスと物理濃縮プロセス, 日本金属学会誌, 10.2320/jinstmet.ja202107, Vol.85, No.8, pp.294-304, 2021.08, Spent automobile catalysts are the most important secondary resource for platinum group metals (PGMs), and their recycling is essential not only to ensure a steady supply of PGMs but also to preserve the natural environment. However, several factors limit the efficiency of PGM recovery in current recycling processes. Specifically, PGMs represent a small proportion of the entire catalyst and are difficult to dissolve in aqueous solutions for subsequent separation. In recent decades, multiple technologies have been developed to make the recycling of PGMs more efficient and environment–friendly. Herein, we introduce the typical industrial processes for recovering PGMs from spent catalysts as well as established and emerging trends in the technological development of PGM recycling. Furthermore, we review novel recycling techniques for converting PGMs in spent catalysts into more soluble states and/or physically concentrating PGMs from spent catalysts.. |
| 8. |
谷ノ内勇樹, 宇田哲也, 京都大学における非鉄製錬分野の産学連携 ~非鉄製錬学講座の取り組み~, まてりあ, 10.2320/materia.59.477, Vol.59, No.9, pp.477-480, 2020.09. |
| 9. |
Yu-ki Taninouchi, Naoki Saito, Akihiro Kishimoto, Tetsuya Uda, Fundamental Study on the E-scrap Recycling Technique Using Alkaline Medium, Proceedings of the COM 2019 Hosting Copper 2019, 2019.08. |
| 10. |
谷ノ内 勇樹, 岡部 徹, 触媒スクラップ中の白金族金属を効率的に分離回収する新技術の開発, マツダ財団研究報告, Vol.30, pp.206-213, 2018.04. |
| 11. |
谷ノ内勇樹, 非鉄製錬学の永続を目指して ~京都大学での新たな取り組み~, 季刊 資源と素材, Vol.3, No.2, pp.100-102, 2018.04. |
| 12. |
谷ノ内勇樹, 塩化マグネシウム溶融塩中でのカソード分極によるチタン合金からの固溶酸素除去, チタン, Vol.65, No.4, p.211, 2017.10. |
| 13. |
谷ノ内勇樹, 岡部徹, 特集「貴金属のリサイクル関連技術の最前線」によせて, 日本金属学会誌, 10.2320/jinstmet.jpr2017901, Vol.81, No.4, p.151, 2017.04. |
| 14. |
Yu-ki Taninouchi, Toru H. Okabe, Vapor Treatment for Alloying and Magnetizing Platinum Group Metals, Rare Metal Technology 2017, 10.1007/978-3-319-51085-9_12, pp.119-127, 2017.02. |
| 15. |
Yu-ki Taninouchi, Yuki Hamanaka, Toru H. Okabe, Titanium Recycling Process Based on A Chlorination Reaction Utilizing Chloride Waste, Proceedings of the 13th World Conference on Titanium, 10.1002/9781119296126.ch25, pp.165-170, 2016.05. |
| 16. |
Toru. H. Okabe, Yu-ki Taninouchi, Recycling Titanium and Its Alloys by Utilizing Molten Salt, Proceedings of 10th International Conference on Molten Slags, Fluxes and Salts (MOLTEN16), pp.751-760, 2016.05. |
| 17. |
Yu-ki Taninouchi, Akinari Suzue, Toru. H. Okabe, Upgrade of autocatalyst scrap for recycling platinum group metals, Proceedings of the 53th Annual Conference of Metallurgists (COM 2014), 2014.09. |
| 18. |
谷ノ内 勇樹, 岡部 徹, レアメタル・貴金属のリサイクル, OHM, Vol.100, No.6, pp.2-3, 2013.06. |
| 19. |
谷ノ内 勇樹, 加藤 直樹, 溶融錫とコルソン系銅合金の界面における金属間化合物の成長, 三菱マテリアル中央研究所R&Dレビュー, No.1, pp.73-77, 2012.01. |
| 20. |
加藤 直樹, 谷ノ内 勇樹, めっき技術を活用した高機能銅合金条の開発, 三菱マテリアル中央研究所R&Dレビュー, Vol.1, pp.46-52, 2012.01. |
| 21. |
Tetsuya Uda, Yu-ki Taninouchi, Yasuhiro Awakura, Chemical Stabilities of Superprotonic Solid Acid Electrolyte: Cesium Hydrogen Sulfate and Cesium Dihydrogen Phosphate, Proceedings of the 16th IKETANI Conference 2006, pp.409-421, 2006.11. |
