Enhancement of Catalytic Activity on Pd/C and Te–Pd/C During the Oxidative Dehydrogenation of Sodium Lactate to Pyruvate in an Aqueous Phase Under Pressurized Oxygen
Article
First Online:
Received:
Revised:
Accepted:
- 216 Downloads
- 16 Citations
Abstract
The oxidative dehydrogenation of sodium lactate to sodium pyruvate in an aqueous phase proceeded favorably using Pd/C and that doped with Te at 358 K with no adjustment in solution pH under pressurized oxygen, although previous reports had stated that this reaction would not proceed using Pd/C while Pd/C doped with either Pb, Bi or Te showed the activity at atmospheric pressure, 363 K, and a pH of 8.
Keywords
Oxidative dehydrogenation Sodium lactate and pyruvate Pd/C High pressure conditionsNotes
Acknowledgments
This work was funded by Grants-in-Aid for Scientific Research (A) KAKENHI 20241020 to SS. The EXAFS study was performed with the approval of the Photon Factory Advisory Committee of the High-Energy Research Organization (Proposal 2007G007).
References
- 1.Corma A, Iborra S, Velty A (2007) Chem Rev 107:2411CrossRefGoogle Scholar
- 2.Erlenmeyer E (1881) Ber Dtsch Chem Ges 14:320CrossRefGoogle Scholar
- 3.Ai M, Ohdan K (1997) Appl Catal A 165:461CrossRefGoogle Scholar
- 4.Ai M, Ohdan K (2000) J Mol Catal A 159:19CrossRefGoogle Scholar
- 5.Ai M (2002) Appl Catal A 234:235CrossRefGoogle Scholar
- 6.Sugiyama S, Shigemoto N, Masaoka N, Suetoh S, Kawami H, Miyaura K, Hayashi H (1993) Bull Chem Soc Jpn 66:1542CrossRefGoogle Scholar
- 7.Hayashi H, Sugiyama S, Masaoka N, Shigemoto N (1995) Ind Eng Chem Res 34:135CrossRefGoogle Scholar
- 8.Hayashi H, Sugiyama S, Moriga T, Masaoka N, Yamamoto A (1997) Stud Surf Sci Catal 108:421CrossRefGoogle Scholar
- 9.Hayashi H, Sugiyama S, Kokawa N, Kato K (1997) Appl Surf Sci 121/122:378CrossRefGoogle Scholar
- 10.Tsujino T, Ohigashi S, Sugiyama S, Kawashiro K, Hayashi H (1992) J Mol Catal 71:25CrossRefGoogle Scholar
- 11.Hayashi H, Sugiyama S, Shigemoto N, Miyaura K, Tsujino S, Kawashiro K, Urabe S (1993) Catal Lett 19:369CrossRefGoogle Scholar
- 12.Hayashi H, Sugiyama S, Katayama Y, Kawashiro K, Shigemoto N (1994) J Mol Catal 91:129CrossRefGoogle Scholar
- 13.Hayashi H, Sugiyama S, Katayama Y, Sakai K, Sugino M, Shigemoto N (1993) J Mol Catal 83:207CrossRefGoogle Scholar
- 14.Katayama Y (1994) Master Thesis of the University of Tokushima, JapanGoogle Scholar
- 15.Sugiyama S, Hirata Y, Nakagawa K, Sotowa K-I, Maehara K, Himeno Y, Ninomiya W (2008) J Catal 206:157CrossRefGoogle Scholar
- 16.Smits PCC, Kuster BFM, van der Wiele K, van der Baan HS (1986) Carbohydr Res 153:227CrossRefGoogle Scholar
- 17.Smits PCC, Kuster BFM, van der Wiele K, van der Baan HS (1987) Appl Catal 33:83CrossRefGoogle Scholar
- 18.Lindlar H, Dubis R (1966) In: Corey EJ (ed) Organic synthesis, vol 46. Wiley, New York, p 89Google Scholar
- 19.Stachurski J, Thomas JM (1988) Catal Lett 1:67CrossRefGoogle Scholar
- 20.Takehira K, Mimoun H, de Roch IS (1979) J Catal 58:155CrossRefGoogle Scholar
- 21.Cheng CH, Dooley KM, Proce GL (1989) J Catal 116:325CrossRefGoogle Scholar
- 22.Gronvol F, Rost E (1956) Acta Chem Scand 10:1620CrossRefGoogle Scholar
- 23.Ziemecki SB, Jones GA, Swartzfager DG, Harlow RL (1985) J Am Chem Soc 107:4547CrossRefGoogle Scholar
Copyright information
© Springer Science+Business Media, LLC 2009