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Improvement of the high energy ball-milling preparation procedure of CO tolerant Pt and Ru containing catalysts for polymer electrolyte fuel cells (2000)

Denis, M.C. ; Gouérec, P. ; Guay, D. ; [et al.]

Springer

Journal of applied electrochemistry 30 (2000), S. 1243-1253

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ISSN: 1572-8838

Keywords: mechanical alloying ; PEFC ; PEM fuel cell ; process control agent ; Pt–Ru alloy

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Electrical Engineering, Measurement and Control Technology

Notes: Abstract Ball-milling has been used to prepare performing CO tolerant polymer electrolyte fuel cell anode catalysts that contain Pt and Ru. The catalyst precursors are obtained by milling together Pt, Ru and a dispersing agent in the atomic ratio 0.5, 0.5 and 4.0. This precursor is not easily recovered after milling because it sticks to the walls of the vial and on the grinding balls. However, the precursor is recovered as a powder when a process control agent (PCA) is added during the milling step. Various PCAs have been used. The PCA should not interfere with the electrocatalytic activity of the catalysts obtained by leaching the precursor. The best preparation of catalyst precursors are obtained by milling: (i) Pt, Ru and Al (dispersing agent) in the atomic ratio 0.5, 0.5, 4.0 + 10 wt% NaF (PCA) or (ii) Pt , Ru and MgH2 in the 0.5, 0.5, 4.0 atomic or molecular ratio. In this case, MgH2 plays at the same time the role of a dispersing agent and that of a PCA. The catalysts are obtained by leaching Al and NaF in (i) or MgH2 in (ii). The CO tolerance of these catalysts is equivalent to that of Pt0.5Ru0.5 Black from Johnson Matthey. The ball-milled catalysts have a surface area comprised between 30 and 44 m2 g−1. As-prepared catalysts are mainly made of metallic Pt and metallic plus oxidized Ru. After fuel cell tests, Pt is completely metallic while the oxidized Ru content decreases but does not disappear. These catalysts are composed of particles with crystallites of two different sizes: in (i) nanocrystallites (∼4 nm) that contain essentially Pt alloyed with Al and perhaps some Ru, and larger (≥∼30 nm) crystallites that contain essentially Ru; in (ii) Pt nanocrystalline particles that may contain some Ru and larger particles that contain essentially either Ru or Pt.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1026542821607

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Myocardial hibernation – adaptation to ischemia (2000)

Schulz, R. ; Heusch, G.

Springer

Zeitschrift für Kardiologie 89 (2000), S. 101-108

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ISSN: 1435-1285

Keywords: Key words Ischemia – reperfusion – hibernation

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The concept of myocardial hibernation implies a downregulation of contractile function as an adaptation to a reduction in myocardial blood flow that serves to maintain myocardial integrity and viability during persistent ischemia. Unequivocal evidence for this concept exists in scenarios of myocardial ischemia that last for several hours; the recovery of energy and substrate metabolism, the potential for recruitment of inotropic reserve at the expense of metabolic recovery, and lack of necrosis are established criteria of short-term hibernation. Furthermore, experimental studies have demonstrated regional myocardial dysfunction at reduced resting blood flow that recovered upon reperfusion, which is consistent with chronic hibernation. In patients, the importance of reduced baseline blood flow vs. that of superimposed reetitive stunning is somewhat controversial; however, in most studies blood flow is reduced, and the myocardium must be ischemic often enough to have persistent dysfunction. Morphologically, hibernating myocardium displays features of dedifferentiation with loss of cardiomyocytes and myofibrils and of degeneration with increased interstitial fibrosis. The mechanisms of short-term hibernation, apart from reduced calcium responsiveness, are not clear at present. With the identification of the underlying mechanism(s) of hibernation, it can potentially be recruited and reinforced pharmacologically to delay impending myocardial infarction.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/

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