J.J.P. Biermann scite author profile

This work is concerned with sequestration of elemental Hg at high temperatures (900-1100• C) on a sorbent that is mineral based, rather than carbon based. This sorbent consists of an intimate mixture of CaO, CaCO 3 , and Al 2 O 3 -2SiO 2 , and is manufactured in industrially relevant quantities (metric tons) from residues produced in paper recycling processes. In contrast to activated carbon (AC), this noncarbon based sorbent has special advantages in that, it can actually enhance fly ash utilization for cement manufacture, rather than diminish it, as is the case for AC.Disperse phase experiments have been conducted, using an externally heated quartz tube reactor, with sorbent feeding rates ranging from 1 to 6 g/h. Preliminary results indicate that Hg removal efficiency is sensitive to sorbent feed rates and to furnace temperature. The Hg removal percentage increased with both these variables. Two mechanisms come into play: an in-flight Hg sorption mechanism, and an Hg sorption mechanism related to sorbent deposits on the reactor wall. A maximum total (in-flight plus deposit-related) Hg removal efficiency of 83-90% was obtained at temperatures of 900-1100• C. There was negligible sorption by either mechanism at temperatures below 600 • C. Results for the in-flight mechanism alone showed a maximum sorption efficiency at ∼900• C, whereas that on the reactor surface increased monotonically with temperature. This suggests that sorbent deactivation can occur in-flight at high temperatures, which is in agreement with other fixed bed results obtained in this laboratory. Deactivation was not apparent for the sorbent-related substance formed on the reactor wall. Raw and spent sorbents were analyzed by X-ray diffraction (XRD) and scanning electron microscopy with energy dispersive spectrophotometer (SEM-EDS) to identify the sorbent mineral transitions that seem to activate the process. The in-flight mechanisms appear to involve (1) activation of the sorbent, caused most probably by an internal solid-solid reaction, followed by (2) Hg sorption, and (3) possible deactivation, if the temperatures are too high for longer period. Reactor surface mechanisms still remain to be elucidated. 

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Molybdena on silica catalysts: selective catalytic oxidation of ammonia to nitrogen over MoO3 on siO2 catalysts

Biermann

Janssen

Boer

et al. 1990

Journal of Molecular Catalysis

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Valence states of vanadia-on-titania/silica and molybdena-on-silica catalysts after reduction and oxidation

Biermann¹,

Janssen²,

Ross³

1990

J. Phys. Chem.

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The use of DSC to study the selective catalytic reduction of NO with NHs

Biermann¹,

Daas²,

Janssen³

1988

Thermochimica Acta

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J.J.P. Biermann

Nitrogen containing species as intermediates in the oxidation of ammonia over silica supported molybdena catalysts

High‐temperature sequestration of elemental mercury by noncarbon based sorbents

Molybdena on silica catalysts: selective catalytic oxidation of ammonia to nitrogen over MoO3 on siO2 catalysts

Valence states of vanadia-on-titania/silica and molybdena-on-silica catalysts after reduction and oxidation

The use of DSC to study the selective catalytic reduction of NO with NHs

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