Adrian Kammer scite author profile

Historical photographs document that during the last century, forests have expanded upwards by 60-80 m into former tundra of the pristine Ural mountains. We assessed how the shift of the high-altitude treeline ecotone might affect soil organic matter (SOM) dynamics. On the gentle slopes of Mali Iremel in the Southern Urals, we (1) determined the differences in SOM stocks and properties from the tundra at 1360 m above sea level (a.s.l.) to the subalpine forest at 1260 m a.s.l., and (2) measured carbon (C) and nitrogen (N) mineralization from tundra and forest soils at 7 and 20 1C in a 6-month incubation experiment. C stocks of organic layers were 3.6 AE 0.3 kg C m À2 in the tundra and 1.9 AE 0.2 kg C m À2 in the forest. Mineral soils down to the bedrock stored significantly more C in the forest, and thus, total soil C stocks were slightly but insignificantly greater in the forest ( 1 3 kg C m À2 ). Assuming a space for time approach based on tree ages suggests that the soil C sink due to the forest expansion during the last century was at most 30 g C m À2 yr À1 . Diffuse reflective infrared spectroscopy and scanning calorimetry revealed that SOM under forest was less humified in both organic and mineral horizons and, therefore, contained more available substrate. Consistent with this result, C mineralization rates of organic layers and A horizons of the forest were two to four times greater than those of tundra soils. This difference was similar in magnitude to the effect of increasing the incubation temperature from 7 to 20 1C. Hence, indirect climate change effects through an upward expansion of forests can be much larger than direct warming effects (D0.3 K across the treeline). Net N mineralization was 2.5 to six times greater in forest than in tundra soils, suggesting that an advancing treeline likely increases N availability. This may provide a nutritional basis for the fivefold increase in plant biomass and a tripling in productivity from the tundra to the forest. In summary, our results suggest that an upward expansion of forest has small net effects on C storage in soils but leads to changes in SOM quality, accelerates C cycling and increases net N mineralization, which in turn might stimulate plant growth and thus C sequestration in tree biomass.

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Determination of organic and inorganic carbon, δ¹³C, and nitrogen in soils containing carbonates after acid fumigation with HCl

Walthert

Graf

Kammer

et al. 2010

Z. Pflanzenernähr. Bodenk.

121

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In carbonate-containing soils a reliable determination of organic C requires a method that effectively separates organic and inorganic C without altering the organic matter. This study was conducted to determine whether HCl vapor completely removes carbonates even in dolomiterich soils and to what extent a widely used acid-fumigation method has to be modified for humus-rich soils. Furthermore, it was tested whether HCl fumigation alters organic-C content. Since C and N parameters are often analyzed simultaneously we also tested the influence of acid-vapor treatment on N content and on d 13 C of soil organic matter. We applied fumigation with 37% HCl for 8 and 32 h using 9 carbonate-containing soil samples. Inorganic C ranged from 7 to 124 and organic C from 9 to 267 g kg -1 . The maximum contents of dolomite and calcite were 940 and 640 g kg -1 , respectively. A time of 8 h was enough to completely remove all carbonates. Neither the content nor the d 13 C of organic C were significantly affected by fumigation. In contrast, N contents were altered by acid treatment. Based on these results and on our experience in analyzing more than 1000 soil samples, a recommended procedure for acid fumigation of carbonate-containing soils with a wide range of organic-and inorganic-C contents was derived. Samples pretreated in this way can be analyzed reliably for their organic-C content and d 13 C. Furthermore, N and inorganic-C contents can be determined with a quality sufficient for many purposes.

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Nitrogen addition alters mineralization dynamics of ¹³C‐depleted leaf and twig litter and reduces leaching of older DOC from mineral soil

Hagedorn

Kammer

Schmidt

et al. 2011

Global Change Biology

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Recent reviews indicate that N deposition increases soil organic matter (SOM) storage in forests but the undelying processes are poorly understood. Our aim was to quantify the impacts of increased N inputs on soil C fluxes such as C mineralization and leaching of dissolved organic carbon (DOC) from different litter materials and native SOM. We added 5.5 g N m−2 yr−1 as NH4NO3 over 1 year to two beech forest stands on calcareous soils in the Swiss Jura. We replaced the native litter layer with 13C‐depleted twigs and leaves (δ13C: −38.4 and −40.8‰) in late fall and measured N effects on litter‐ and SOM‐derived C fluxes. Nitrogen addition did not significantly affect annual C losses through mineralization, but altered the temporal dynamics in litter mineralization: increased N inputs stimulated initial mineralization during winter (leaves: +25%; twigs: +22%), but suppressed rates in the subsequent summer. The switch from a positive to a negative response occurred earlier and more strongly for leaves than for twigs (−21% vs. 0%). Nitrogen addition did not influence microbial respiration from the nonlabeled calcareous mineral soil below the litter which contrasts with recent meta‐analysis primarily based on acidic soils. Leaching of DOC from the litter layer was not affected by NH4NO3 additions, but DOC fluxes from the mineral soils at 5 and 10 cm depth were significantly reduced by 17%. The 13C tracking indicated that litter‐derived C contributed less than 15% of the DOC flux from the mineral soil, with N additions not affecting this fraction. Hence, the suppressed DOC fluxes from the mineral soil at higher N inputs can be attributed to reduced mobilization of nonlitter derived ‘older’ DOC. We relate this decline to an altered solute chemistry by NH4NO3 additions, an increased ionic strength and acidification resulting from nitrification, rather than to a change in microbial decomposition.

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Application of a quantum cascade laser-based spectrometer in a closed chamber system for real-time δ13C and δ18O measurements of soil-respired CO2

Kammer

Tuzson

Emmenegger

et al. 2011

Agricultural and Forest Meteorology

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Mineralisation, leaching and stabilisation of <sup>13</sup>C-labelled leaf and twig litter in a beech forest soil

Kammer

Hagedorn

2011

Biogeosciences

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Abstract. Very few field studies have quantified the different pathways of C loss from decomposing litter even though the partitioning of C fluxes is essential to understand soil C dynamics. Using 0.75 kg m −2 of 13 Cdepleted leaf (δ 13 C = −40.8 ‰) and 2 kg m −2 of twig litter (δ 13 C = −38.4 ‰), we tracked the litter-derived C in soil CO 2 effluxes, dissolved organic C (DOC), and soil organic matter of a beech forest in the Swiss Jura. Autotrophic respiration was reduced by trenching. Our results show that mineralisation was the main pathway of C loss from decomposing litter over 1 yr, amounting to 24 and 31 % of the added twig and leaf litter. Contrary to our expectations, the leaf litter C was mineralised only slightly (1.2 times) more rapidly than the twig litter C. The leaching of DOC from twigs amounted to half of that from leaves throughout the experiment (2 vs. 4 % of added litter C). Tracing the litter-derived DOC in the soil showed that DOC from both litter types was mostly removed (88-96 %) with passage through the top centimetres of the mineral soil (0-5 cm) where it might have been stabilised. In the soil organic C at 0-2 cm depth, we indeed recovered 4 % of the initial twig C and 8 % of the leaf C after 1 yr. Much of the 13 C-depleted litter remained on the soil surface throughout the experiment: 60 % of the twig litter C and 25 % of the leaf litter C. From the gap in the 13 C-mass balance based on C mineralisation, DOC leaching, C input into top soils, and remaining litter, we inferred that another 30 % of the leaf C but only 10 % of twig C could have been transported via soil fauna to soil depths below 2 cm. In summary, over 1 yr, twig litter was mineralised more rapidly relative to leaf litter than expected, and much less of the twig-derived C was transported to the mineral soil than of the leaf-derived C. BothCorrespondence to: A. Kammer (adrian.kammer@wsl.ch) findings provide some evidence that twig litter could contribute less to the C storage in these base-rich forest soils than leaf litter.

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Adrian Kammer

Treeline shifts in the Ural mountains affect soil organic matter dynamics

Determination of organic and inorganic carbon, δ¹³C, and nitrogen in soils containing carbonates after acid fumigation with HCl

Nitrogen addition alters mineralization dynamics of ¹³C‐depleted leaf and twig litter and reduces leaching of older DOC from mineral soil

Application of a quantum cascade laser-based spectrometer in a closed chamber system for real-time δ13C and δ18O measurements of soil-respired CO2

Mineralisation, leaching and stabilisation of <sup>13</sup>C-labelled leaf and twig litter in a beech forest soil

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Adrian Kammer

Treeline shifts in the Ural mountains affect soil organic matter dynamics

Determination of organic and inorganic carbon, δ13C, and nitrogen in soils containing carbonates after acid fumigation with HCl

Nitrogen addition alters mineralization dynamics of 13C‐depleted leaf and twig litter and reduces leaching of older DOC from mineral soil

Application of a quantum cascade laser-based spectrometer in a closed chamber system for real-time δ13C and δ18O measurements of soil-respired CO2

Mineralisation, leaching and stabilisation of &lt;sup&gt;13&lt;/sup&gt;C-labelled leaf and twig litter in a beech forest soil

Contact Info

Product

Resources

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Determination of organic and inorganic carbon, δ¹³C, and nitrogen in soils containing carbonates after acid fumigation with HCl

Nitrogen addition alters mineralization dynamics of ¹³C‐depleted leaf and twig litter and reduces leaching of older DOC from mineral soil

Mineralisation, leaching and stabilisation of <sup>13</sup>C-labelled leaf and twig litter in a beech forest soil