Degradation Pathways for Monoethanolamine in a CO<sub>2</sub> Capture Facility

Strazisar, Brian R.; Anderson, R. Rox; White, Curt M.

doi:10.1021/ef020272i

Cited by 327 publications

(297 citation statements)

References 13 publications

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“…Most of the amines tested showed very little oxidative degradation and this makes it difficult to propose degradation mechanisms for the formation of new degradation compounds. In general it seems like the formation of degradation compounds follows the same patterns as earlier described for the formation of de-methylated amines (secondary and tertiary amines) or secondary products as HEF analogues, HEI, OZD analogues, alkylamines and ammonia (da Silva et al, 2012; Lepaumier et al, 2011b;Lepaumier et al, 2009b;Strazisar et al, 2003;.…”

Section: Other Aminessupporting

confidence: 62%

“…Thermal degradation with CO2 was studied by Davies, Lepaumier and Eide-Haugmo (Davis, 2009;Eide-Haugmo, 2011;Lepaumier et al, 2009a) and oxidative degradation by Lepaumier (Lepaumier et al, 2009b). Increased attention on oxidative degradation was seen after pilot plant samples showed high degree of similarity to degradation compounds found in oxidative degradation experiments (da Silva et al, 2012;Lepaumier et al, 2011a;Strazisar et al, 2003). The oxidative degradation experiments reported have been performed in variations of two setups, either in a closed-batch reactor at elevated temperature and oxygen pressure (Lepaumier et al, 2009b;Supap et al, 2001;Wang and Jens, 2011) or in an open-batch reactor at 55 °C, where the solution would be sparged with a wet gas blend of CO2 and O2/air (da Silva et al, 2012;Goff and Rochelle, 2004;Lepaumier et al, 2011b;Sexton and Rochelle, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Oxidative degradation of amines using a closed batch system

Vevelstad

Grimstvedt

Einbu

et al. 2013

International Journal of Greenhouse Gas Control

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Oxidative degradation experiments on five amines and two amino acids were performed in a new closed setup at atmospheric pressure. For most of the amines/amino acids significant degradation was not present under these conditions, except for MEA and MMEA. The degradation compounds found seem to follow the same patterns as described in literature. Volatile compounds as ammonia and alkylamine play an important role in understanding the initial degradation mechanisms. For MMEA, methylamine and ammonia were found in the same order of magnitude. Oxygen stochiometry of the degradation compounds could not be explained by initial air in the system. Oxygen in some of the degradation compounds could come from oxygen diffusing into the system as seen from proposed model and/or water reacting with iminium giving aldehyde and amine/ammonia. Temperature and dissolved metal seemed to influence oxygen and degradation rate for the MEA experiments.

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Section: Other Aminessupporting

confidence: 62%

Section: Introductionmentioning

confidence: 99%

Oxidative degradation of amines using a closed batch system

Vevelstad

Grimstvedt

Einbu

et al. 2013

International Journal of Greenhouse Gas Control

View full text Add to dashboard Cite

show abstract

“…Thermal degradation has been studied by several research groups over a long period of time (Davis and Rochelle, 2009;Eide-Haugmo, 2011;Lepaumier et al, 2009a;Polderman et al, 1955) while oxidative degradation has received increased attention the last decade (Goff and Rochelle, 2004;Lepaumier et al, 2009;Rooney et al, 1998;Supap et al, 2001) as it was discovered that oxidative degradation compounds are the main products under real plant conditions (da Silva et al, 2012;Lepaumier et al, 2011a;Strazisar et al, 2003). Increased insight into the degradation mechanisms, through knowledge of stoichiometry, kinetics, and chemical pathways, may result in methods for eliminating or strongly reducing degradation.…”

Section: Introductionmentioning

confidence: 99%

“…The initial mechanisms are still unclear, but the general impression is that the mechanisms either start with abstraction of an electron from the lone pair of nitrogen or abstraction of hydrogen from the nitrogen, α-carbon, or β-carbon, or a combination of these depending on the amine structure, nature of oxidants, pH, solvent effects and concentrations (Bedell, 2009;Chi and Rochelle, 2002;Rochelle, 2004, 2006;Hull et al, 1967;Hull et al, 1969;Rosenblatt et al, 1967;Sexton, 2008) Secondary degradation compounds are formed by reactions between primary degradation compounds and amines forming for example amides as N-(2-hydroxyethyl)-formamide (HEF), N-(2-hydroxyethyl)-acetamide (HEA) and N,-oxamide (BHEOX) from MEA and acid, or aldehyde and oxygen, and imidazoles as N-(2-hydroxyethyl)imidazole (HEI) from ammonia, MEA and several aldehydes. Lately several mechanisms have been suggested for the formation of secondary degradation compounds (da Silva et al, 2012;Lepaumier et al, 2011a;Strazisar et al, 2003). However, there are still many unanswered questions regarding factors influencing the formation of these degradation compounds.…”

Section: Introductionmentioning

confidence: 99%

Oxidative degradation of 2-ethanolamine: The effect of oxygen concentration and temperature on product formation

Vevelstad

Grimstvedt

Elnan

et al. 2013

International Journal of Greenhouse Gas Control

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Oxidative degradation experiments on 2-ethanolamine (MEA) were performed at four different oxygen concentrations and at two temperatures. MEA loss and degradation product build-up were measured. Increasing the temperature from 55 to 75 °C was shown to have higher impact on the MEA loss than increasing the oxygen concentration from 21 to 98%. Liquid end sample analyses were performed for all experiments and overall nitrogen balance tests were conducted for the experiments at 21% O2 (run 2), 50% O2 and 98% O2. Analysis of liquid and gas phase ammonia and MEA in the solvent was found to give a good overall picture of degradation in the MEA system. The degradation products formed at the different oxygen concentrations were the same as described in earlier literature. However, it was found that oxygen affects the formation of the individual degradation products differently. At 75 o C the development of degradation product concentrations with time was more complex. Laboratory reaction experiments were used to verify the formation of certain degradation products from some of the suggested mechanisms.

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“…The MEA reclaimer waste is considered to be a hazardous waste (24). This was further proved by a study performed by NETL, Pittsburgh, which identified chemical species (MEA, ammonia, 3-hydroxyethylamino-N-hydroxyethyl propanamide, 4-hydroxyethyl-2-piperizinone, 2-hydroxyethylamino-N-hydroxyethyl acetamide, and N-acetyletylethanolamine) in the reclaimer waste that are considered to be hazardous (25,26). Entrainment of MEA with the treated flue gas will be at most a few parts per million and is minimized with the addition of a wash section in the top portion of the absorber column.…”

Section: Environmental Impactsmentioning

confidence: 95%