リケラボ論文検索は、全国の大学リポジトリにある学位論文・教授論文を一括検索できる論文検索サービスです。

リケラボ 全国の大学リポジトリにある学位論文・教授論文を一括検索するならリケラボ論文検索大学・研究所にある論文を検索できる

リケラボ 全国の大学リポジトリにある学位論文・教授論文を一括検索するならリケラボ論文検索大学・研究所にある論文を検索できる

大学・研究所にある論文を検索できる 「Solid-phase extraction of palladium, platinum, and gold from water samples: comparison between a chelating resin and a chelating fiber with ethylenediamine groups」の論文概要。リケラボ論文検索は、全国の大学リポジトリにある学位論文・教授論文を一括検索できる論文検索サービスです。
リケラボ

コピーが完了しました

URLをコピーしました

論文の公開元へ論文の公開元へ
書き出し

Solid-phase extraction of palladium, platinum, and gold from water samples: comparison between a chelating resin and a chelating fiber with ethylenediamine groups

Iwase, Misato Isobe, Kota Zheng, Linjie Takano, Shotaro Sohrin, Yoshiki 京都大学 DOI:10.1007/s44211-023-00270-3

2023.05

概要

Dissolved palladium (Pd), platinum (Pt), and gold (Au) form inert chloride complexes at low concentrations of pmol/kg in environmental water, thus rendering difficulty in the development of a precise analytical method for these metals. Herein, we report the preconcentration of Pd, Pt, and Au with a chelating fiber Vonnel-en and a chelating resin TYP-en with ethylenediamine (en) groups. Batch adsorption experiments reveal the adsorption capacity of Vonnel-en for Pd(II), Pt(IV), and Au(III) in 0.10 M HCl as 0.53, 0.22, and 0.27 mmol/g, respectively. The adsorption capacity of TYP-en for Pd(II), Pt(IV), and Au(III) in 0.10 M HCl is 0.31, 0.17, and 0.52 mmol/g, respectively. In column extraction experiments using small-volume samples containing Pd(II), Pt(II), Pt(IV), Au(I), or Au(III) at concentrations of μmol/kg, TYP-en is able to quantitatively recover Pd, Pt, and Au from 0.01 to 0.2 M HCl irrespective of their oxidation states. In contrast, Vonnel-en is unable to quantitatively recover Au(I). In column extraction experiments using large-volume samples containing Pd(II), Pt(IV), and Au(III) at concentrations of pmol/kg, the recovery of Pd(II), Pt(IV), and Au(III) by TYP-en from 0.07 M HCl is 100–105%. However, the recovery of Pd(II), Pt(IV), and Au(III) by Vonnel-en from 0.03 to 0.3 M HCl is 102–110, 7–15, and 20–52%, respectively. Thus, the chelating resin TYP-en has a high potential for the multielemental determination of Pd, Pt, and Au in environmental water.

論文の公開元へ

この論文で使われている画像

関連論文

関連論文をもっと見る

参考文献

1. J. Kielhorn, C. Melber, D. Keller, I. Mangelsdorf, Int. J. Hyg.

Environ. Health 205, 417 (2002)

2. A. Dubiella-Jackowska, Ż Polkowska, J. Namieśnik, Pol. J. Environ. Stud. 16, 329 (2007)

3. C.W. Corti, R.J. Holliday, Appl. Earth Sci. 114, 115 (2005)

4. K.H. Wedepohl, Geochim. Cosmochim. Acta 59, 1217 (1995)

5. A. Mitra, I.S. Sen, Geochim. Cosmochim. Acta 216, 417 (2017)

6. C. Barbante, A. Veysseyre, C. Ferrari, K.V.D. Velde, C. Morel,

G. Capodaglio, P. Cescon, G. Scarponi, C. Boutron, Environ. Sci.

Technol. 35, 835 (2001)

7. H. Wichmann, G.A.K. Anquandah, C. Schmidt, D. Zachmann,

M.A. Bahadir, Sci. Total Environ. 388, 121 (2007)

8. F. Zereini, H. Alsenz, C.L. Wiseman, W. Puttmann, E. Reimer,

R. Schleyer, E. Bieber, M. Wallasch, Sci. Total Environ. 416, 261

(2012)

9. E. Abdulbur-Alfakhoury, G. Trommetter, N. Brion, D. Dumoulin, M. Reichstadter, G. Billon, M. Leermakers, W. Baeyens, Sci.

Total Environ. 784, 147075 (2021)

10. A. Yessoufou, B.E. Ifon, F. Suanon, B. Dimon, Q. Sun, C.A. Dedjiho, D. Mama, C.P. Yu, Environ. Monit. Assess. 189, 625 (2017)

11. K. Ravindra, L. Bencs, R. Van Grieken, Sci. Total Environ. 318,

1 (2004)

12. Y. Pan, S. Neuss, A. Leifert, M. Fischler, F. Wen, U. Simon, G.

Schmid, W. Brandau, W. Jahnen-Dechent, Small 2007, 3 (1941)

13. C.H. Gammons, Geochim. Cosmochim. Acta 60, 1683 (1996)

14. D.R. Turner, M. Whitfield, A.G. Dickson, Geochim. Cosmochim.

Acta 45, 855 (1981)

15. A. Usher, D.C. McPhail, J. Brugger, Geochim. Cosmochim. Acta

73, 3359 (2009)

16. D.S. Lee, Nature 305, 47 (1983)

17. E.D. Goldberg, V. Hodge, P. Kay, M. Stallard, M. Koide, Appl.

Geochem. 1, 227 (1986)

18. M. Koide, V. Hodge, E.D. Goldberg, K. Bertine, Appl. Geochem.

3, 237 (1988)

13

704

19. K.K. Falkner, J.M. Edmond, Earth Planet. Sci. Lett. 98, 208

(1990)

20. A. Suzuki, H. Obata, A. Okubo, T. Gamo, Mar. Chem. 166, 114

(2014)

21. A.S. Mashio, A. Ichimura, H. Yamagishi, K.H. Wong, H. Obata,

H. Hasegawa, Mar. Chem. 243, 104124 (2022)

22. L. Fischer, G. Smith, S. Hann, K.W. Bruland, Mar. Chem. 199, 44

(2018)

23. K. Liu, X. Gao, L. Li, C.-T.A. Chen, Q. Xing, Chemosphere 212,

429 (2018)

24. A. Cobelo-Garcia, M.E. Mulyani, J. Schafer, Talanta 232, 122289

(2021)

13

M. Iwase et al.

25. H. Hasegawa, S. Barua, T. Wakabayashi, A. Mashio, T. Maki, Y.

Furusho, I.M.M. Rahman, Microchem. J. 139, 174 (2018)

26. X. Chang, Y. Li, G. Zhan, X. Luo, W. Gao, Talanta 43, 407 (1996)

27. P. Tahaei, M. Abdouss, M. Edrissi, A.M. Shoushtari, M. Zargaran,

Materialwiss. Werkstofftech. 39, 839 (2008)

28. L. Niu, S. Deng, G. Yu, J. Huang, Chem. Eng. J. 165, 751 (2010)

29. Y. Sohrin, S. Iwamoto, S. Akiyama, T. Fujita, T. Kugii, H. Obata,

E. Nakayama, S. Goda, Y. Fujishima, H. Hasegawa, K. Ueda, M.

Matsui, Anal. Chim. Acta 363, 11 (1998)

30. Y. Sohrin, S. Urushihara, S. Nakatsuka, T. Kono, E. Higo, T.

Minami, K. Norisuye, S. Umetani, Anal. Chem. 80, 6267 (2008)

...

参考文献をもっと見る

全国の大学の
卒論・修論・学位論文

一発検索!

この論文の関連論文を見る