This
comprehensive critical review combines, for the first time,
recent advances in nanoscale surface chemistry, surface science, DFT,
adsorption calorimetry, and in situ XRD and TEM to provide new insights
into catalyst sintering. This work provides qualitative and quantitative
estimates of the extent and rate of sintering as functions of nanocrystal
(NC) size, temperature, and atmosphere. This review is unique in that
besides summarizing important, useful data from previous studies,
it also advances the field through addition of (i) improved or new
models, (ii) new data summarized in original tables and figures, and
(iii) new fundamental perspectives into sintering of supported metals
and particularly of chemical sintering of supported Co during Fischer–Tropsch
synthesis. We demonstrate how the two widely accepted sintering mechanisms
are largely sequential with some overlap and highly NC-size dependent,
i.e., generally, small NCs sinter rapidly by Ostwald ripening, while
larger NCs sinter slowly by crystallite migration and coalescence.
In addition, we demonstrate how accumulated knowledge, principles,
and recent advances, discussed in this review, can be utilized in
the design of supported metal NCs highly resistant to sintering. Recommendations
for improving the design of sintering experiments and for new research
are addressed.
Pyrolysate gas mixtures are multivariate and relative in nature. Statistical techniques applied to these data generally ignore their relative nature. Published data for permanent gases (CO, CO2, H2, CH4) and tars produced by pyrolysing 15 wildland fuels were reanalysed using compositional data analysis techniques. Mass and mole fractions were compositionally equivalent. Plant species, moisture status and heating mode effects on compositional balances formed from subsets of pyrolysates were tested. Plant species affected the amount of phenol, primary and secondary/tertiary tars relative to permanent gases and relative amounts of single- and multi-ring compounds. Plant moisture status affected the amount of CO relative to other permanent gases, of H2 to CH4 and tars to phenol. Heating mode and rate strongly influenced pyrolysate composition. Slow heating produced more primary tars relative to multi-ring tars than fast heating convective and combined radiant and convective heating modes. Slow heating produced relatively more compounds with fewer rings and fast heating produced relatively more multi-ring compounds. Compositional data analysis is a well-developed statistical methodology, providing models and methods equivalent to traditional ones, that accounts for the special constraining features of relative data. Future analysis of the compositional data related to wildland fire using compositional techniques is recommended.
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