Thermal behaviour of arsenic trioxide adsorbed on activated carbon

Cuypers, Frederic; Dobbelaere, Christopher De; Hardy, An; Bael, Marlies K. Van; Helsen, Lieve

doi:10.1016/j.jhazmat.2008.12.048

Cited by 29 publications

(18 citation statements)

References 28 publications

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“…To explain these findings a two stage mechanism is proposed which agrees with earlier experiments [6,11] using wood model compounds and heavy metal model compounds: arsenic pentoxide, originating from the decomposition of chromium arsenate, part of which has not formed thermally stable compounds with wood minerals (e.g. Cr(III)As(V)Ca(II)), is reduced to arsenic trioxide.…”

Section: Resultssupporting

confidence: 80%

“…At temperatures around 400 • C or higher, the desorption of arsenic trioxide is likely to be the most important process leading to arsenic release. Earlier TGA experiments with arsenic trioxide adsorbed on activated carbon showed a broad desorption peak between 290 • C and 500 • C with a peak temperature at 405 • C [6]. Similar behavior of limited amounts of arsenic trioxide originating from the reduction of arsenic pentoxide (which is the product of chromium arsenate decomposition) could result in a reduced arsenic retention at temperatures of 400 • C or higher.…”

Section: Effect Of Pressure and Process Temperature On Arsenic And Chmentioning

confidence: 87%

“…During pyrolysis CrAsO 4 decomposes to chromium(III) trioxide (Cr 2 O 3 ) and arsenic(V) pentoxide (As 2 O 5 ). Hereafter As 2 O 5 is reduced by reductive pyrolysis vapors to arsenic(III) trioxide (As 2 O 3 ) which sublimates after desorption from the pyrolysis residue matrix [3][4][5][6]. Low temperature pyrolysis aims at controlling or even eliminating this volatilization process by strictly controlling process operating conditions.…”

Section: Introductionmentioning

confidence: 99%

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Pyrolysis of chromated copper arsenate (CCA) treated wood waste at elevated pressure: Influence of particle size, heating rate, residence time, temperature and pressure

Cuypers

Helsen

2011

Journal of Analytical and Applied Pyrolysis

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a b s t r a c tLab-scale pyrolysis experiments with weathered CCA treated wood chips have been performed and the influence of particle size, residence time (10-40 min), heating rate (5-20 • C/min), temperature (330-430 • C) and pressure (0 bar, 5 bar) has been investigated. Few data, covering the pyrolysis of weathered wood was found in the literature and the literature data on pyrolysis experiments with a controlled CCA wood input, showed that results were often highly affected by experimental uncertainty. In order to reduce the uncertainty on the results, a thorough characterization of the wood input has been performed and a ratio method has been proposed which allows to study the effect of particle size on arsenic and chromium volatilization. Larger wood particles show a higher arsenic and chromium retention during pyrolysis which is attributed to the higher mass transfer resistance in these particles. Residence time has a limited effect on arsenic retentions. Increasing heating rate results in a limited increase in arsenic retentions and a more profound increase in chromium retentions. The latter is attributed to a lower average particle temperature during heating caused by the thermal lag in larger particles. Elevated pressure results in a significant increase of arsenic retentions, which is probably due to higher mass transfer resistance. Increasing temperature results in a slight decrease in arsenic retentions till 390 • C, with a sharp decrease at higher temperatures. Chromium retentions are less affected by increasing temperature, especially at higher temperatures. To conclude, a mechanism is proposed for the volatilization of chromium and arsenic during low temperature pyrolysis of CCA wood. Mass transfer resistance and the formation of As 4 O 6 are crucial for the control of arsenic volatilization, while heat transfer resistance and thermal lag are more important for the control of chromium volatilization.

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Section: Resultssupporting

confidence: 80%

Section: Effect Of Pressure and Process Temperature On Arsenic And Chmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

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Pyrolysis of chromated copper arsenate (CCA) treated wood waste at elevated pressure: Influence of particle size, heating rate, residence time, temperature and pressure

Cuypers

Helsen

2011

Journal of Analytical and Applied Pyrolysis

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“…And the emission ratio of arsenic accelerated slightly with the temperature increased, which was similar with the arsenic emissions during the coal pyrolysis (Lu et al, 2004). As 2 O 5 and organic arsenic compounds would decompose to As 2 O 3 (Kakitani et al, 2004) which released easily at a low temperature during the pyrolysis (Cuypers et al, 2009;Helsen et al, 2004). In this study, As 2 S 3 whose melting point is 573 K was also one of the origins that caused arsenic to release at a low temperature.…”

Section: Resultssupporting

confidence: 70%

Inhibitory effects of CaO/Fe2O3 on arsenic emission during sewage sludge pyrolysis

Han

et al. 2016

Bioresource Technology

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This work aimed to investigate effects and reaction mechanisms of CaO/Fe2O3 on emission behaviors of arsenic during sewage sludge pyrolysis. The results showed that 24.8-54.2%, 26.4-60.4% and 27.7-63.1% of arsenic escaped from three samples when pyrolysis process happened at 723, 923 and 1123K respectively. And the sludge which contained higher calcium and iron contents released less arsenic than others. External CaO and Fe2O3 were added into the sewage sludge to study their effects on arsenic emissions during pyrolysis, where both of them inhibited arsenic emission effectively, especially at high temperatures. With the help of thermogravimetry analysis and X-ray fluorescence, inhibitory mechanisms of CaO/Fe2O3 on arsenic emission during sewage sludge pyrolysis were studied. CaO could react with As2O3, As2S3 and NaAsO2 to form nonvolatile substances, such as Ca(AsO2)2; while Fe2O3 could react with NaAsO2 to generate certain substances which was stable below 1123K.

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“…This is consistent with the low sublimation temperature of the arsenolite phase. 20 The low temperature sublimation of arsenolite microcrystals suggests that they are not the source for the apparent increase of arsenic dose upon annealing, reported in the literature. 8,9 SIMS measurement of the capped sample (S2) revealed the presence of a very thin As rich layer at the Si interface.…”

mentioning

confidence: 97%

Formation of arsenolite crystals at room temperature after very high dose arsenic implantation in silicon

Meirer

Giubertoni

Demenev

et al. 2012

Applied Physics Letters

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Thermal behaviour of arsenic trioxide adsorbed on activated carbon

Cited by 29 publications

References 28 publications

Pyrolysis of chromated copper arsenate (CCA) treated wood waste at elevated pressure: Influence of particle size, heating rate, residence time, temperature and pressure

Pyrolysis of chromated copper arsenate (CCA) treated wood waste at elevated pressure: Influence of particle size, heating rate, residence time, temperature and pressure

Inhibitory effects of CaO/Fe2O3 on arsenic emission during sewage sludge pyrolysis

Formation of arsenolite crystals at room temperature after very high dose arsenic implantation in silicon

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