研究者業績

谷口 省吾

タニグチ ショウゴ  (Shogo Taniguchi)

基本情報

所属
大阪産業大学 工学部都市創造工学科 講師
学位
博士(工学)(大阪産業大学)

J-GLOBAL ID
201801009016748370
researchmap会員ID
B000307497

研究キーワード

 2

論文

 31
  • 谷口省吾, 内山善基, 橋口亜由未, 尾崎博明
    環境技術 48(5) 270-277 2019年9月  査読有り
  • 橋口亜由未, 藤川陽子, 米田稔, 谷口省吾, 尾崎博明
    環境技術 44(7) 391-401 2015年7月  査読有り
  • Rabindra Raj Giri, Hiroaki Ozaki, Xiao Guo, Ryohei Takanami, Shogo Taniguchi
    DESALINATION AND WATER TREATMENT 54(13) 3625-3631 2015年6月  査読有り
    The usefulness of ultraviolet-C (UVC: 254nm) and vacuum UV (VUV: 185+ 254nm) photolysis for elimination and mineralization of four selected pharmaceutical compounds (PhCs) in mixed aqueous solution were tested in laboratory batch experiments. UVC photolysis was unable to eliminate moderate and refractory PhCs. Moreover, it was not at all useful for mineralization of the PhCs (<10% TOC removal, 30min reaction) and longer reaction period (i.e. 60min) had no significant positive impact on the mineralization efficiency. On the other hand, VUV photolysis eliminated the PhCs almost completely in a short reaction period irrespective of their nature, and 90% mineralization was achieved in an hour. The greatly enhanced elimination and mineralization efficiencies for VUV photolysis were attributed to accelerated direct and indirect photolysis reactions. Based on the results, it was concluded that VUV photolysis was very promising over UVC photolysis for mineralization of PhCs in mixed aqueous solution. However, more studies are necessary for practical applicability of the method in wastewater treatments.
  • 谷口省吾, 山田修, 尾崎博明
    セラミックス 50(2) 104-108 2015年2月  招待有り
  • Yoko Fujikawa, Masataka Sugahara, Tetsuo Honma, Sayaka Hirayama, Phan Do Hung, Shinji Sakurai, Hiroshi Yashima, Ayumi Hashiguchi, Shogo Taniguchi, Hiroaki Ozaki, Paul Lewtas
    e-Journal of Surface Science and Nanotechnology 13 455-460 2015年  
    © 2015 The Surface Science Society of Japan. We have conducted a pilot study of a biological filtration (BF) system for low-cost arsenic (As) removal from groundwater containing both ferrous iron (Fe(II)) and arsenic (As). Throughout the study, we have observed that arsenite (As(III)) as well as arsenate (As(V)) could be removed with this system. In conventional water treatment technologies, the preoxidation of As(III) to As(V) by oxidizing chemical is a mandatory step for As(III) removal However, such a preoxidation unit has not been used in our BF pilot unit, and hence the mechanisms of As(III) removal by BF have been of interest. Using a flow-through column reactor that simulates the actual BF pond for analysis by X-ray absorption spectroscopy (XAS), we could observe the adsorption of As(III) in water onto iron hydroxides deposited on the biological filter. The time-resolved As K-edge X-ray absorption near-edge structure (XANES) spectra were obtained when the water containing As(III) and Fe(II) was continuously fed to the reactor. An increase in the absorption intensity of the X-ray with time was clearly observed in the time-resolved spectra, indicating that the spectra represented the concentration and chemical state of As adsorbed at the solid-liquid interface of the biological filter. The XAS results also show that while the original water fed to the reactor was supposed to contain only As(III) and Fe(II), a small portion of As(III) was oxidized to As(V) in the influent line when the As(III) solution met the Fe(II) solution before flowing into the reactor. Consequently, besides As(III), As(V) probably formed by the oxidation of As(III) in the influent, was detected on the filter by XAS. The results demonstrate that, in BF, mechanisms of As(III) removal are at least partially explained by the adsorption of As(III) in the raw water to the biological filter as it is.

MISC

 7

講演・口頭発表等

 25

担当経験のある科目(授業)

 5

共同研究・競争的資金等の研究課題

 10

研究テーマ

 2
  • 研究テーマ
    微量汚染物質を対象とした廃水処理方法の開発
    研究期間(開始)
    2012/04/01
  • 研究テーマ
    水および土壌等の環境における新規微量汚染物質の分析法の開発
    研究期間(開始)
    2012/04/01

免許・資格

 1
  • 免許・資格名
    公害防止管理者 水質関係第1種
    取得年月日
    2017/12/15