Catalytic Filter Systems with Direct and Indirect Soot Oxidation Activity

Konstandopoulos, Athanasios G.; Papaioannou, Eleni; Zarvalis, Dimitrios; Skopa, Sofia; Baltzopoulou, Penelope; Kladopoulou, Evdoxia; Kostoglou, Margaritis; Λορέντζου, Σουζάνα

doi:10.4271/2005-01-0670

Cited by 44 publications

(30 citation statements)

References 11 publications

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“…TEM studies by Gardini et al [15] on Ag/soot mixtures have indicated that tight contact corresponds to an extensive interface between primary particles of catalyst and soot, whereas loose contact corresponds to fewer contact points at the interface between coagulates of catalyst particles and coagulates of soot particles. In several experiments [11,[16][17][18][19][20] with oxidation of soot particles filtered from gas streams by a catalytic filter part of the soot oxidation has been observed to peak at a relatively low temperature in the range characteristic of tight contact with the catalyst, while another part of the soot oxidation has been observed to peak at a higher temperature more characteristic of loose contact with the catalyst. Hence an understanding of both tight and loose contact oxidation may be relevant for real filter applications.…”

Section: Introductionmentioning

confidence: 99%

Importance of the oxygen bond strength for catalytic activity in soot oxidation

Christensen

Grunwaldt

Jensen

2016

Applied Catalysis B: Environmental

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The oxygen bond strength on a catalyst, as measured by the heat of oxygen chemisorption, is observed to be a very important parameter for the activity of the catalyst in soot oxidation. With both intimate contact between soot and catalyst (tight contact) and with the solids stirred loosely together (loose contact) the rate constants for a number of catalytic materials outline a volcano curve when plotted against their heats of oxygen chemisorption. However, the optima of the volcanoes correspond to different heats of chemisorption for the two contact situations. In both cases the activation energies for soot oxidation follow linear Brønsted-Evans-Polanyi relationships with the heat of oxygen chemisorption. Among the tested metal or metal oxide catalysts Co 3 O 4 and CeO 2 were nearest to the optimal bond strength in tight contact oxidation, while Cr 2 O 3 was nearest to the optimum in loose contact oxidation. The optimum of the volcano curve in loose contact is estimated to occur between the bond strengths of α-Fe 2 O 3 and α-Cr 2 O 3 . Guided by an interpolation principle Fe a Cr b O x binary oxides were tested, and the activity of these oxides was observed to pass through an optimum for an FeCr 2 O x binary oxide catalyst, which exhibited a rate constant at 550 °C that was 2.3 times higher than the one for pure α-Cr 2 O 3 and 29 times higher than the one for pure α-Fe 2 O 3 .

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Section: Introductionmentioning

confidence: 99%

Importance of the oxygen bond strength for catalytic activity in soot oxidation

Christensen

Grunwaldt

Jensen

2016

Applied Catalysis B: Environmental

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“…In tests where soot and catalyst are crushed together (so-called tight contact), the oxidation occurs at a significantly lower temperature, compared to when soot and catalyst are stirred together with a spatula (so-called loose contact) [11]. Several experiments with diesel soot filters [10,[12][13][14][15] have indicated the presence of both contact types. An explanation of this may come from the environmental scanning electron microscopy experiments by Kameya and Lee [16], who observed that the catalytic oxidation at the interface between the bottom of the soot cake and the catalyst containing filter caused the soot cake to crack, leading to a delamination and subsequent diminishment or even loss of soot/catalyst contact [16].…”

Section: Introductionmentioning

confidence: 99%

Visualizing the mobility of silver during catalytic soot oxidation

Gardini

Christensen

Damsgaard

et al. 2016

Applied Catalysis B: Environmental

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The catalytic activity and mobility of silver nanoparticles used as catalysts in temperature programmed oxidation of soot:silver (1:5 wt:wt) mixtures have been investigated by means of flow reactor experiments and in situ environmental transmission electron microscopy (ETEM). The carbon oxidation temperature was significantly lower compared to uncatalyzed soot oxidation with soot and silver loosely stirred together (loose contact) and lowered further with the two components crushed together (tight contact). The in situ TEM investigations revealed that the silver particles exhibited significant mobility during the soot oxidation, and this mobility, which increases the soot/catalyst contact, is expected to be an important factor for the lower oxidation temperature. In the intimate tight contact mixture the initial dispersion of the silver particles is greater, and the onset of mobility occurs at a lower temperature which is consistent with the lower oxidation temperature of the tight contact mixture.

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“…The double peak is therefore a direct manifestation of the importance that catalyst layer geometry plays in establishing different modes of contact between the deposited soot particles and the catalytic coating. It is not possible to explain this double peak structure of the soot oxidation curves with a model based only on chemistry, since uncatalyzed soot oxidation exhibits a single peak and the same is true for mixtures of soot-catalyst powders 67) . An example of application of the two-layer model to analyze the soot conversion on a catalytic filter is shown in Fig.…”

Section: Layer Ii: Soot Cake Layermentioning

confidence: 99%

“…The problem of soot-catalyst contact in diesel emission control systems was recognized in the 1980s 63) as a barrier for active catalytic filter development, and it has become popularized in more recent laboratory studies of powdered carbon blackcatalyst mixtures, with the introduction of so-called "loose" and "tight" contact 64,65) samples. Direct demonstration of soot-catalyst contact effects on diesel soot oxidation in filters has been published in 67) . A mathematical description of the incomplete sootcatalyst contact, the so-called "Two-Layer Model" was introduced a decade ago, and it has been since incorporated into state-of-the-art DPF simulators 68,69,70,71) .…”

Section: Catalytic Oxidation Mechanismsmentioning

confidence: 99%