Carbon isotope anomaly in the major plant C&amp;lt;sub&amp;gt;1&amp;lt;/sub&amp;gt; pool and its global biogeochemical implications

Keppler, Frank; Kalin, Robert M.; Harper, David B.; McRoberts, W. Colin; Hamilton, John T. G.

doi:10.5194/bg-1-123-2004

Cited by 119 publications

(150 citation statements)

References 36 publications

(40 reference statements)

Supporting

Mentioning

131

Contrasting

Order By: Relevance

“…An exceptional case amongst the NMHCs is CH 3 OH which emitted significantly depleted 13 C with respect to the material burned, as shown by Yamada et al (2009). They attribute changes to the emission δ 13 C signature to the variations in the fraction of the precursor material (pectin vs. lignin methoxy pools; see also Keppler et al, 2004) and kinetic effects in loss processes. The overall depletion of CH 3 OH with respect to the plant material is found to linearly correlate with the fire-modified combustion efficiency (MCE = CO 2 /( CO + CO 2 ), denotes trace gas concentration enhancement due to emission).…”

Section: Biomass Burning Emissionsmentioning

confidence: 99%

“…For the fractionation escorting isoprene emission, the lower limit of 4 ‰ depletion relative to the bulk leaf composition from Affek and Yakir (2003) is taken. In the case of methanol, significantly larger depletions (about 40 ‰) were discovered by Keppler et al (2004) and linked to highly depleted pectin and lignin methoxyl pools which plants likely use to produce CH 3 OH. A later work by Yamada et al (2010) confirmed similar fractionations for a different set of C 3 plants species.…”

Section: Plant Emissionsmentioning

confidence: 99%

“…δ 13 C uncertainty is derived from δ 13 C(CO 2 ) = 0.02 ‰ and leaf discrimination uncertainty of = 2 ‰. Exceptionally, methanol δ 13 C = 6.6 ‰ is augmented by the uncertainty of plant emission fractionation (Keppler et al, 2004;Yamada et al, 2010, ±6.3 ‰;see text). g Following Manning et al (1997).…”

Section: Uncertaintiesmentioning

confidence: 99%

See 2 more Smart Citations

Uncertainties of fluxes and 13C  ∕ 12C ratios of atmospheric reactive-gas emissions

2017

View full text Add to dashboard Cite

Abstract. We provide a comprehensive review of the proxy data on the 13 C / 12 C ratios and uncertainties of emissions of reactive carbonaceous compounds into the atmosphere, with a focus on CO sources. Based on an evaluated set-up of the EMAC model, we derive the isotope-resolved data set of its emission inventory for the 1997-2005 period. Additionally, we revisit the calculus required for the correct derivation of uncertainties associated with isotope ratios of emission fluxes. The resulting δ 13 C of overall surface CO emission in 2000 of −(25.2 ± 0.7) ‰ is in line with previous bottom-up estimates and is less uncertain by a factor of 2. In contrast to this, we find that uncertainties of the respective inverse modelling estimates may be substantially larger due to the correlated nature of their derivation. We reckon the δ 13 C values of surface emissions of higher hydrocarbons to be within −24 to −27 ‰ (uncertainty typically below ±1 ‰), with an exception of isoprene and methanol emissions being close to −30 and −60 ‰, respectively. The isotope signature of ethane surface emission coincides with earlier estimates, but integrates very different source inputs. δ 13 C values are reported relative to V-PDB.

show abstract

Section: Biomass Burning Emissionsmentioning

confidence: 99%

Section: Plant Emissionsmentioning

confidence: 99%

See 1 more Smart Citation

Uncertainties of fluxes and 13C  ∕ 12C ratios of atmospheric reactive-gas emissions

2017

View full text Add to dashboard Cite

show abstract

“…Apart from biotic production of living plants, an abiotic reaction pathway has been described for CH3Br following a nucleophilic substitution reaction (SN2) (Hamilton et al, 2003;Keppler et al, 2004). The methoxy groups of pectin and lignin, both abundant cell-stabilizing macromolecules, react with halide ions dissolved in the tissue water of the plants (Khan et al, 2001) (Fig.…”

Section: Introductionmentioning

confidence: 99%

“…Hence stable isotope techniques are starting to be explored to improve the source apportionment of methyl halides. Carbon-13 analysis on atmospheric samples was first shown for CH3Cl by Rudolph et al (1997) and since then it was applied in various studies to characterize source (Thompson et al, 2002;Keppler et al, 2004;Saito and Yokouchi, 2008) and sink signatures (Gola et al, 2005;Sellevag et al, 2006). A first δ 13 C isotope based budget estimate was accomplished by Keppler et al (2005).…”

Section: Introductionmentioning

confidence: 99%

Stable bromine isotopic composition of methyl bromide released from plant matter

Horst

Holmstrand

Andersson

et al. 2014

Geochimica et Cosmochimica Acta

View full text Add to dashboard Cite

Methyl bromide (CH3Br) emitted from plants constitutes a natural source of bromine to the atmosphere, and is a component in the currently unbalanced global CH3Br budget. In the stratosphere, CH3Br contributes to ozone loss processes.Studies of stable isotope composition may reduce uncertainties in the atmospheric CH3Br budget, but require well-constrained isotope fingerprints of the source end members. Here we report the first measurements of stable bromine isotopes (δ 81 Br) in CH3Br from abiotic plant emissions. Incubations of both KBr-fortified pectin, a ubiquitous cell-stabilizing macromolecule, and of a natural halophyte (Salicornia fruticosa), yielded an enrichment factor (ε) of -2.00±0.23‰ (1σ, n=8) for pectin and -1.82±0.02‰ (1σ, n=4) for Salicornia (the relative amount of 81 Br decreased in CH3Br compared to the substrate salt). For short incubations, and up to 10% consumption of the salt substrate, this isotope effect was similar for temperatures from 30 up to 300°C. For longer incubations of up to 100 hours at 180°C the δ 81 Br values increased from -2‰ to 0‰ for pectin and to -1‰ for Salicornia. These δ 81 Br source signatures of CH3Br formation from plant matter combine with similar data for carbon isotopes to facilitate multidimensional isotope diagnostics of the CH3Br budget.

show abstract

References Part I

Meier‐Augenstein¹

2010

Stable Isotope Forensics

View full text Add to dashboard Cite

Carbon isotope anomaly in the major plant C<sub>1</sub> pool and its global biogeochemical implications

Cited by 119 publications

References 36 publications

Uncertainties of fluxes and <sup>13</sup>C  ∕ <sup>12</sup>C ratios of atmospheric reactive-gas emissions

Uncertainties of fluxes and <sup>13</sup>C  ∕ <sup>12</sup>C ratios of atmospheric reactive-gas emissions

Stable bromine isotopic composition of methyl bromide released from plant matter

References Part I

Contact Info

Product

Resources

About

Carbon isotope anomaly in the major plant C&lt;sub&gt;1&lt;/sub&gt; pool and its global biogeochemical implications

Cited by 119 publications

References 36 publications

Uncertainties of fluxes and &lt;sup&gt;13&lt;/sup&gt;C ∕ &lt;sup&gt;12&lt;/sup&gt;C ratios of atmospheric reactive-gas emissions

Uncertainties of fluxes and &lt;sup&gt;13&lt;/sup&gt;C ∕ &lt;sup&gt;12&lt;/sup&gt;C ratios of atmospheric reactive-gas emissions

Stable bromine isotopic composition of methyl bromide released from plant matter

References Part I

Contact Info

Product

Resources

About

Carbon isotope anomaly in the major plant C<sub>1</sub> pool and its global biogeochemical implications

Uncertainties of fluxes and <sup>13</sup>C  ∕ <sup>12</sup>C ratios of atmospheric reactive-gas emissions

Uncertainties of fluxes and <sup>13</sup>C  ∕ <sup>12</sup>C ratios of atmospheric reactive-gas emissions