Structure of Bimetallic Particles:  Nonequimolar Graphite-Supported Fe−Pd

Wunder, Robert; Phillips, Jonathan

doi:10.1021/jp960478i

Cited by 23 publications

(14 citation statements)

References 17 publications

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“…The (111) peak position in Fe-Pd appears at a slightly higher scattering angle compared to that of Pd nanoparticles, indicating the formation of a Pd-Fe alloy. 80,81 XPS analysis of the as-synthesized Pd-Fe/GCN was conducted to elucidate the composition and oxidation state of metal present in the nanohybrids as shown in Fig. 5.…”

Section: Resultsmentioning

confidence: 99%

Bimetallic Pd₉₆Fe₄ nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

2019

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Section: Resultsmentioning

confidence: 99%

Bimetallic Pd₉₆Fe₄ nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

2019

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“…Instrument. Microcalorimetry techniques have an excellent potential for providing unprecedented insight into the structure and surface chemistry of high surface area materials, such as acid catalysts [53], supported metal catalysts [54], as well as carbons [55][56][57]. They can provide precise information concerning the concentration and nature of the active sites existing on carbon surfaces.…”

Section: Microcalorimetrymentioning

confidence: 99%

“…The microcalorimeter used in this work was designed , built and developed under the direction of Dr. Jonathan Phillips. Earlier reports from this lab describe an instrument which can be built with readily available equipment [54,57,58]. However, the instrument described earlier suffered from several limitations.…”

Section: Microcalorimetrymentioning

confidence: 99%

OPTIMIZATION OF CHAR FOR NOx REMOVAL

Phillips¹,

Radović²,

Xia³

et al. 1999

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Work performed for this study demonstrates that the temperature of treatment and the identity of the treatment gas both strongly impact the surface chemistry of activated carbon. Two commercial activated carbons were treated in either N 2 or H 2 at different temperatures up to 2600 o C. Several techniques-including microcalorimetry, point of zero charge measurements, thermal desorption-were used to provide insight into important aspects of the chemical surface properties. The results show that activated carbons treated at high temperatures (ca. 950 o C) in hydrogen will not react with oxygen and water at ambient temperatures; moreover, surfaces created in this fashion have stable properties in ambient conditions for many months. In contrast, the same carbons treated in an inert gas (e.g., N 2) will react strongly with oxygen and water at ambient temperatures. In the presence of platinum (or any other noble metal), stable basic carbons, which will not adsorb oxygen in ambient laboratory conditions, can be created via a relatively low-temperature process. Treatment at higher temperatures (>1500 o C) produced increasingly stable surfaces in either N 2 or H 2. A structural model is proposed. To wit: Treatment at high temperatures in any gas will lead to the desorption of oxygen surface functionalities in the form of CO and/or CO 2. Absent any atom rearrangement, the desorption of these species will leave highly unsaturated carbon atoms ("dangling carbons") on the surface, which can easily adsorb O 2 and H 2 O. In an inert gas these "dangling carbons" will remain, but hydrogen treatments will remove these species and leave the surface with less energetic sites, which can only adsorb O 2 at elevated temperatures. Specifically, hydrogen reacts with any

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“…This last result is not surprising given that only on the weakly interacting support did a true surface alloy form. Calorimetric, XRD, TEM and MES studies of graphite supported iron-iridium [33], and iron palladium [34,35] were also carried out. In each equimolar metal case calorimetric studies of oxygen adsorption revealed that the surface was primarily metallic iron after a low temperature reduction and a bulk alloy after a high temperature reduction.…”

Section: Kmentioning

confidence: 99%

Microcalorimetric studies of the structure of supported bimetallic catalyst particles

Phillips

1997

Journal of Thermal Analysis

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Microcalorimetric studies of oxygen and hydrogen chemisorption during the last decade improved the understanding of the structure and structural dynamics of supported bimetallic catalyst particles. For example, it was found that on graphitic supports two different reduced surface compositions/structures can be created for base metal/noble metal particles. Appropriate treatments "switch" the surface from almost pure reduced base metal to true alloy. Calorimetric studies also indicate support interactions play a major role in controlling bimetallic particle surface structure. In contrast to behaviour found on graphitic supports, iron/noble metal particles supported on refractory oxides apparently do not form alloy surfaces. The reduced surface is dominated by the noble metal. Several studies indicate the value of the models of surface composition/structure developed using microcalorimetry for predicting the activity/selectivity of bimetallic particles.

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Structure of Bimetallic Particles: Nonequimolar Graphite-Supported Fe−Pd

Cited by 23 publications

References 17 publications

Bimetallic Pd₉₆Fe₄ nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

Bimetallic Pd₉₆Fe₄ nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

OPTIMIZATION OF CHAR FOR NOx REMOVAL

Microcalorimetric studies of the structure of supported bimetallic catalyst particles

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Structure of Bimetallic Particles: Nonequimolar Graphite-Supported Fe−Pd

Cited by 23 publications

References 17 publications

Bimetallic Pd96Fe4 nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

Bimetallic Pd96Fe4 nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

OPTIMIZATION OF CHAR FOR NOx REMOVAL

Microcalorimetric studies of the structure of supported bimetallic catalyst particles

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Bimetallic Pd₉₆Fe₄ nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts

Bimetallic Pd₉₆Fe₄ nanodendrites embedded in graphitic carbon nanosheets as highly efficient anode electrocatalysts