Селективное каталитическое окисление до многофункциональных органических кислот, страница 14

[63] Mirescu, A. and U. Prusze, A new environmental friendly method for the preparation of sugar acids via catalytic oxidation on gold catalysts. Applied Catalysis B, Environmental, 2007. 70(1): p. 644-652.

[64] Baatz, C., Thielecke, N. and U. Prusze, Influence of the preparation conditions on the properties of gold catalysts for the oxidation of glucose. Applied Catalysis B, Environmental, 2006. 70 (1-4): p. 353-360.

[65] A. Abad, C. Almela, A. Corma, H. Garcıґa, Tetrahedron 62 (2006) 6666–6672.

[66] Ishida, T., et al., Aerobic oxidation of glucose and 1-phenylethanol over gold nanoparticles directly deposited on ion-exchange resins. Applied Catalysis A, General, 2009. 353(2): p. 243-248.

[67] Ishida T., Kinoshita N., et.al. Influence of the Support and the Size of Gold Clusters on Catalytic Activity for Glucose Oxidation. Angew. Chem. Int. Ed., 2008. 47: p. 9265.

[68] Murzina, E.V., et al., d-Lactose oxidation over gold catalysts. Catalysis Today, 2008. 131(1): p. 385-392.

[69] Mirescu, A. and U. Prüße, Selective glucose oxidation on gold colloids. Catalysis Communications, 2006. 7(1): p. 11-17.

[70] Biella, S., L. Prati, and M. Rossi, Gold catalyzed oxidation of aldehydes in liquid phase. Journal of Molecular Catalysis A: Chemical, 2003. 197(1): p. 207-212.

[71] Beltrame, P., et al., Aerobic oxidation of glucose. II. Catalysis by colloidal gold. Applied Catalysis A, General, 2006. 297: p. 1-7.

[72] Ketchie, W.C., et al., Influence of gold particle size on the aqueous-phase oxidation of carbon monoxide and glycerol. Journal of Catalysis, 2007. 250(1): p. 94-101.

[73] Hermans, S. and M. Devillers, On the role of ruthenium associated with Pd and/or Bi in carbon-supported catalysts for the partial oxidation of. Applied Catalysis A: General, 2002. 235(1): p. 253-264.

[74] Besson, M., et al., Catalytic Oxidation of Glucose on Bismuth-Promoted Palladium Catalysts. Journal of Catalysis, 1995. 152(1): p. 116-121.

[75] Abbadi A., van Bekkum H. 1995. Highly selective oxidation to 2-keto-aldonic acids over Pt-Bi and Pt-Pb catalysts. Appl. Catal. A: General. 124: 105-115.

[76] Abbadi A. Gotlied K.F., Meiberg J.B.M., van Bekkum H. 1997. Sélective Chemo-Catalytic Oxidation of Lactose and/of Lactobionic Acid towards 1-Carboxylactulose (2-keto-Lactobionic Acid). Appl. Catal. A: General. 156: 105.

[77] Hendriks H. E.J., Kuster B. F.M., Marin G. B. 1990. The Effect of Bismuth on the Selective Oxidation of Lactose on Supported Palladium Catalysts. Carbohydr. Res. 204:121.

[78] Wenkin, M., et al., The role of bismuth as promoter in Pd-Bi catalysts for the selective oxidation of glucose to gluconate. Journal of Molecular Catalysis A: Chemical, 2002. 180(1): p. 141-159.

[79] Karski S., Paryjczak T., Witonska I. 2003. Selective Oxidation of Glucose to Gluconic Acid over Bimetallic Pd-Me Catalysts (Me= Bi, Tl, Sn, Co). Kinet. Catal. 44:619.

[80] Karski, S. and I. Witonska, Bismuth as an additive modifying the selectivity of palladium catalysts. Journal of Molecular Catalysis A: Chemical, 2003. 191(1): p. 87-92.

[81] Hermans, S. and M. Devillers, On the role of ruthenium associated with Pd and/or Bi in carbon-supported catalysts for the partial oxidation of. Applied Catalysis A: General, 2002. 235(1): p. 253-264.

[82] Karski, S., Activity and selectivity of Pd-Bi/SiO2 catalysts in the light of mutual interaction between Pd and Bi. Journal of Molecular Catalysis. A, Chemical, 2006. 253(1): p. 147-154.

[83] Baatz, C., Prusze, U., Preparation of gold catalysts for glucose oxidation, Catal. Today. 2007. 122(3): p. 325.

[84] M. Wenkin, R. Touillaux, P. Ruiz, B. Delmon, M. Devillers. Influence of metallic precursors on the properties of carbon-supported bismuth-promoted palladium catalysts for the selective oxidation of glucose to gluconic acid. Appl. Catal. A 148 (1996) 181.