A consistent molecular hydrogen isotope chemistry scheme based on an independent bond approximation

Pieterse, G.; Krol, Maarten; Röckmann, T.

doi:10.5194/acp-9-8503-2009

Cited by 30 publications

(52 citation statements)

References 82 publications

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“…As originally proposed by Gerst and Quay (2001) from budget closure, the photochemical sources of H 2 are also enriched in deuterium with δD between ∼ +100 ‰ and +200 ‰, (Rahn et al, 2003;Röckmann et al, 2003Röckmann et al, , 2010bFeilberg et al, 2007;Nilsson et al, 2007Nilsson et al, , 2010Pieterse et al, 2009 (Novelli et al, 1999;Hauglustaine and Ehhalt, 2002;Ehhalt and Rohrer, 2009;Pieterse et al, 2011) the extreme deuterium depletion relative to ambient atmospheric H 2 makes it a quite important contributor to the isotope budget (Price et al 2007;Pieterse et al 2011). An increasing demand and anthropogenic biological production of H 2 by e.g., industrial fermentation of biogenic waste material is associated with an expected release to the atmosphere because of leakage during production, storage, transport and use.…”

Section: Abstract Biologically Produced Molecular Hydrogen (H 2 )mentioning

confidence: 96%

The stable isotopic signature of biologically produced molecular hydrogen (H<sub>2</sub>)

et al. 2012

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Abstract. Biologically produced molecular hydrogen (H 2 )is characterised by a very strong depletion in deuterium. Although the biological source to the atmosphere is small compared to photochemical or combustion sources, it makes an important contribution to the global isotope budget of H 2 . Large uncertainties exist in the quantification of the individual production and degradation processes that contribute to the atmospheric budget, and isotope measurements are a tool to distinguish the contributions from the different sources. Measurements of δD from the various H 2 sources are scarce and for biologically produced H 2 only very few measurements exist.Here the first systematic study of the isotopic composition of biologically produced H 2 is presented. In a first set of experiments, we investigated δD of H 2 produced in a biogas plant, covering different treatments of biogas production. In a second set of experiments, we investigated pure cultures of several H 2 producing microorganisms such as bacteria or green algae. A Keeling plot analysis provides a robust overall source signature of δD = −712 ‰ (±13 ‰) for the samples from the biogas reactor (at 38 • C, δD H 2 O = +73.4 ‰), with a fractionation constant ε H 2 -H 2 O of −689 ‰ (±20 ‰) between H 2 and the water. The five experiments using pure culture samples from different microorganisms give a mean source signature of δD = −728 ‰ (±28 ‰), and a fractionation constant ε H 2 -H 2 O of −711 ‰ (±34 ‰) between H 2 and the water. The results confirm the massive deuterium depletion of biologically produced H 2 as was predicted by the calculation of the thermodynamic fractionation factors for hydrogen exchange between H 2 and water vapour. Systematic errors in the isotope scale are difficult to assess in the absence of international standards for δD of H 2 .As expected for a thermodynamic equilibrium, the fractionation factor is temperature dependent, but largely independent of the substrates used and the H 2 production conditions. The equilibrium fractionation coefficient is positively correlated with temperature and we measured a rate of change of 2.3 ‰ / • C between 45 • C and 60 • C, which is in general agreement with the theoretical prediction of 1.4 ‰ / • C.Our best experimental estimate for ε H 2 -H 2 O at a temperature of 20 • C is −731 ‰ (±20 ‰) for biologically produced H 2 . This value is close to the predicted value of −722 ‰, and we suggest using these values in future global H 2 isotope budget calculations and models with adjusting to regional temperatures for calculating δD values.

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Section: Abstract Biologically Produced Molecular Hydrogen (H 2 )mentioning

confidence: 96%

The stable isotopic signature of biologically produced molecular hydrogen (H<sub>2</sub>)

et al. 2012

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“…Recently, isotope effects in the production processes of H 2 have been studied (Gerst and Quay, 2001;Rahn et al, 2002bRahn et al, , 2003Röckmann et al, 2003;Rhee et al, 2006a;Feilberg et al, 2007;Rhee et al, 2008;Röckmann et al, 2010a,b;Vollmer et al, 2010;Walter et al, 2011;Haumann et al, 2012), as well as the isotope effects in the H 2 uptake by soils (Gerst and Quay, 2001;Rahn et al, 2002a;Rice et al, 2011). Two chemical transport models have been adapted to incorporate the stable isotopic composition of H 2 , namely GEOS-CHEM (Price et al, 2007) and TM5 (Pieterse et al, 2009(Pieterse et al, , 2012, and many more δD data have become available for the validation of such models (Rice et al, 2010;Batenburg et al, 2011). However, for obvious practical reasons, most of these data were collected at ground level, and yield little information about processes higher up in the atmosphere, particularly in the Upper TroposphereLower Stratosphere (UTLS) region.…”

Section: Stable Isotope Studies Of Hmentioning

confidence: 99%

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

et al. 2012

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Abstract. More than 450 air samples that were collected in the upper troposphere -lower stratosphere (UTLS) region by the CARIBIC aircraft (Civil Aircraft for the Regular Investigation of the atmosphere Based on an Instrument Container) have been analyzed for molecular hydrogen (H 2 ) mixing ratios (χ (H 2 )) and H 2 isotopic composition (deuterium content, δD).More than 120 of the analyzed samples contained air from the lowermost stratosphere (LMS). These show that χ(H 2 ) does not vary appreciably with O 3 -derived height above the thermal tropopause (TP), whereas δD does increase with height. The isotope enrichment is caused by H 2 production and destruction processes that enrich the stratospheric H 2 reservoir in deuterium (D); the exact shapes of the profiles are mainly determined by mixing of stratospheric with tropospheric air. Tight negative correlations are found between δD and the mixing ratios of methane (χ(CH 4 )) and nitrous oxide (χ (N 2 O)), as a result of the relatively long lifetimes of these three species. Samples that were collected from the Indian subcontinent up to 40 • N before, during and after the summer monsoon season show no significant seasonal change in χ(H 2 ), but δD is up to 12.3 ‰ lower in the July, August and September monsoon samples. This δD decrease is correlated with the χ(CH 4 ) increase in these samples. The significant correlation with χ (CH 4 ) and the absence of a perceptible χ(H 2 ) increase that accompanies the δD decrease indicates that microbial production of very D-depleted H 2 in the wet season may contribute to this phenomenon.Some of the samples have very high χ (H 2 ) and very low δD values, which indicates a pollution effect. Aircraft engine exhaust plumes are a suspected cause, since the effect mostly occurs in samples collected close to airports, but no similar signals are found in other chemical tracers to support this. The isotopic source signature of the H 2 pollution seems to be on the low end of the signature for fossil fuel burning.

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“…Evidence of a substantial enrichment in the deuterium content of formaldehyde is from theoretical and box model considerations of the oxidative chain between hydrocarbons and formaldehyde [Gerst and Quay, 2001;Rahn et al, 2003;Röckmann et al, 2003;Feilberg et al, 2007;Pieterse et al, 2009]; direct observations of the enrichment in dD of stratospheric H 2 as a result of CH 4 oxidation [Rahn et al, 2003;Röckmann et al, 2003]; photochemical modeling of the dD of H 2 in the troposphere and stratosphere [Price et al, 2007;Mar et al, 2007]; and observations of formaldehyde enriched in deuterium up to 210‰ [Rice and Quay, 2009]. The photochemical enrichment of formaldehyde must be sufficient to overcome a −450‰ to −500‰ isotope effect occurring with the photolysis of formaldehyde [Feilberg et al, 2007;Rhee et al, 2008].…”

Section: Climatological Mean Distribution Of H 2 and Dd-hmentioning

confidence: 99%

Meridional distribution of molecular hydrogen and its deuterium content in the atmosphere

Rice¹,

Quay²,

Stutsman³

et al. 2010

J. Geophys. Res.

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The atmospheric molecular hydrogen concentration and its deuterium abundance were measured in remote air samples collected onboard six Pacific Ocean ship transects between 37°N and 77°S during years 2001 through 2005. The data reveal a year‐round interhemispheric gradient in H2 concentration and isotopic composition with the extratropical Northern Hemisphere lower in H2 concentration by 17 ± 11 ppb and δD of H2 by 16 ± 12‰ than the Southern Hemisphere (95% confidence). On the basis of these snapshots, the interhemispheric gradient in δD was observed to be smallest in September through November, a time that experiences the largest gradient in concentration, and the largest in April, a time that has a small gradient in concentration. A simple hemispheric box model of the atmosphere indicates that, while the hemispheric asymmetry in soil sink of H2 is primarily responsible for the observed interhemispheric gradient in H2 concentration, the hemispheric difference in the δD of the H2 sources and sinks are equally responsible for the observed interhemispheric gradient in δD. Both the inverse correlation between interhemispheric H2 and δD gradients and their seasonal changes point to the importance of the H2 produced by photochemical sources. Comparisons with a three‐dimensional chemical transport model shows reasonable agreement with mean behavior in both variables and provides an accounting for H2 sources and sinks within ±15% without a dramatic change in the H2 budget. Anomalous H2 concentrations and δD in tropics and low‐latitude regions observed during the November–December 2001 meridional H2 and δD snapshot is thought to be a result of H2 emissions from biomass burning, possibly from continental Africa.

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A consistent molecular hydrogen isotope chemistry scheme based on an independent bond approximation

Cited by 30 publications

References 82 publications

The stable isotopic signature of biologically produced molecular hydrogen (H<sub>2</sub>)

The stable isotopic signature of biologically produced molecular hydrogen (H<sub>2</sub>)

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

Meridional distribution of molecular hydrogen and its deuterium content in the atmosphere

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A consistent molecular hydrogen isotope chemistry scheme based on an independent bond approximation

Cited by 30 publications

References 82 publications

The stable isotopic signature of biologically produced molecular hydrogen (H&lt;sub&gt;2&lt;/sub&gt;)

The stable isotopic signature of biologically produced molecular hydrogen (H&lt;sub&gt;2&lt;/sub&gt;)

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

Meridional distribution of molecular hydrogen and its deuterium content in the atmosphere

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The stable isotopic signature of biologically produced molecular hydrogen (H<sub>2</sub>)

The stable isotopic signature of biologically produced molecular hydrogen (H<sub>2</sub>)