DRIFTS band areas as measured pool size proxy to reduce parameter uncertainty in soil organic matter models

Laub, Moritz; Demyan, Michael Scott; Nkwain, Yvonne Funkuin; Blagodatsky, Sergey; Kätterer, Thomas; Piepho, Hans‐Peter; Cadisch, Georg

doi:10.5194/bg-17-1393-2020

Cited by 19 publications

(8 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The disk was then scanned with the FTIR spectroscopy (Tensor‐27, Bruker, Germany) as an average of 50 scans over the spectral range of 4,000–400 cm −1 at 4 cm −1 resolution (wavenumber). Based on the FTIR relative absorption spectra (Figure S7 in Supporting Information S1), we chose the peak at ∼1,620 cm −1 attributed to the stretching vibration of C=C from aromatics and C=O from carboxylate and amides, and the peaks at ∼2,850 and ∼2,920 cm −1 corresponding to the stretching vibration of C‐H from aliphatic ‐CH 3 and ‐CH 2 ‐ groups (Demyan et al., 2012; Flanagan et al., 2020; Laub et al., 2020; Zaccone et al., 2007). Given that C=C from aromatics and C=O from carboxylate and amides are more recalcitrant than C‐H from aliphatic ‐CH 3 and ‐CH 2 ‐ groups (Demyan et al., 2012; Laub et al., 2020), we calculated the ratio of peak value at 1,620 cm −1 to the sum of peak values at 2,850 cm −1 and 2,920 cm −1 (abbreviated as r1620/(2850 + 2920)) to characterize substrate quality.…”

Section: Methodsmentioning

confidence: 99%

Mineral and Climatic Controls Over Soil Organic Matter Stability Across the Tibetan Alpine Permafrost Region

Fang

Chen

Qin

et al. 2021

Global Biogeochemical Cycles

View full text Add to dashboard Cite

Permafrost thaw could accelerate microbial decomposition, lead to greenhouse gases emissions into the atmosphere, and thus trigger a positive feedback to climate warming. As a key parameter reflecting the resistance of soil organic matter (SOM) to be decomposed by microorganisms, SOM stability may determine the strength of permafrost carbon (C)‐climate feedback. Adequate understanding of patterns and drivers of SOM stability can thus contribute to predicting permafrost C cycle and its feedback to climate change. However, due to limited observations, it remains unknown whether biochemical selectivity or physico‐chemical protection dominates SOM stability in permafrost regions. By combining large‐scale soil sampling, thermal analysis and random forest model, we quantified SOM stability in the top 10 cm using thermogravimetry and differential scanning calorimetry, and explored its spatial patterns across the Tibetan alpine permafrost region. We then constructed structural equation model to evaluate the relative importance of climatic variables, edaphic properties, substrate quality, and mineral variables in regulating SOM stability over a broad geographic scale. Our results indicated that SOM stability exhibited an increasing tendency from the southeastern to northwestern plateau. The stronger SOM stability was associated with higher mineral‐organic associations and more arid conditions. By contrast, substrate quality had limited effects on SOM stability. Overall, these results provide large‐scale evidence for the physico‐chemical protection hypothesis, highlighting the importance of considering mineral variables in Earth system models to better predict soil C dynamics across permafrost regions.

show abstract

Section: Methodsmentioning

confidence: 99%

Mineral and Climatic Controls Over Soil Organic Matter Stability Across the Tibetan Alpine Permafrost Region

Fang

Chen

Qin

et al. 2021

Global Biogeochemical Cycles

View full text Add to dashboard Cite

show abstract

“…Maximum absorbance were selected for specific peaks in the wavelength ranges of 2930-2850 cm −1 (aliphatic compounds), 1660-1600 cm −1 (aromatic compounds), 1510-1500 cm −1 (lignin), 1260-1210 cm −1 (cellulose) and 893-852 cm −1 (aromatic compounds) according to ranges identified previously (e.g. Chatterjee et al, 2012;Laub et al, 2020;Yeasmin et al, 2017). Two ratios of aliphatic/aromatic (using the aromatic peaks at 1630 and 880 cm −1 respectively) and one of cellulose/lignin were calculated to assess qualitatively SOC dynamics with depth.…”

Section: Sample Laboratory Analysismentioning

confidence: 99%

“…The SOC quality, here referring to its compound-specific composition (i. e. aliphatic, aromatic or cellulose-and lignin-like compounds) and decomposition state, is a good proxy for vegetation and SOC dynamics. It can be assessed by mid-infrared spectroscopy that is a semiquantitative, but highly efficient approach (Laub et al, 2020;Ramirez et al, 2021) in combination with organic carbon analyses ( 13 C, C:N).…”

Section: Introductionmentioning

confidence: 99%

Soil organic carbon stocks and quality in small-scale tropical, sub-humid and semi-arid watersheds under shrubland and dry deciduous forest in southwestern India

et al. 2022

View full text Add to dashboard Cite

Soil organic carbon is regulated by a dynamic interaction of vegetation inputs, organic matter degradation and stabilization processes in soils, and its redistribution in the landscape. Tropical ecosystems are highly important in terms of carbon stored in vegetation and soil, but many processes of the soil carbon cycle in the tropics are yet to be fully understood. Here, we studied soil organic carbon stocks and quality in small-scale tropical, sub-humid and semi-arid watersheds along a climate gradient in southwestern India with varying vegetation and geology to identify major drivers of soil organic carbon dynamics in three prevalent soil types (Lixisol, Vertisol and Ferralsol) under shrubland and dry deciduous forest. We used a combination of organic carbon analysis (total organic carbon content, 13C, C:N), midinfrared spectroscopy and soil property information (bulk density, texture, oxides, pH, cation-exchange capacity). Soil organic carbon stocks in these watersheds showed a substantial range from 58.2 to 169.4 Mg C ha− 1 in the first 60 cm, and the differences depended on local-to watershed-scale variations in vegetation type and history, geology, soil physio-chemical (clay, oxides) and biological (bioturbation) properties. Considerable parts of the organic carbon stored in these soils was found below 30 cm (up to 40 %), stressing the importance of tropical subsoils. From our analysis of the soil organic carbon quality and literature data on paleoclimate and vegetation, we could identify land-use changes in these watersheds, from tropical moist evergreen forests, forest-savannah transitions and plantations to secondary regrowth forest over time. Our study provides new data and insights into the local-scale drivers of soil organic carbon quantity and quality of tropical, sub-humid and semi-arid watersheds under shrubland and dry deciduous forest with varying geology and soil types.

show abstract

“…Hence, SOM composition (the prevalence of certain biochemical compounds) may serve as a proxy for ecosystem properties and soil functioning, as it affects C cycling by the amount of energy provided to soil microorganisms (Nunan et al, 2015;Barré et al, 2016). Furthermore, the peak areas related to biochemical SOM compounds have been successfully used to parameterize fast-and slow-cycling SOM pools (Todd-Brown et al, 2013;Bailey et al, 2018;Laub et al, 2020;Baldock et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Soil geochemistry as a driver of soil organic matter composition: insights from a soil chronosequence

et al. 2022

View full text Add to dashboard Cite

Abstract. A central question in carbon research is how stabilization mechanisms in soil change over time with soil development and how this is reflected in qualitative changes in soil organic matter (SOM). To address this matter, we assessed the influence of soil geochemistry on bulk SOM composition along a soil chronosequence in California, USA, spanning 3 million years. This was done by combining data on soil mineralogy and texture from previous studies with additional measurements on total carbon (C), stable isotope values (δ13C and δ15N), and spectral information derived from diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS). To assess qualitative shifts in bulk SOM, we analysed the peak areas of simple plant-derived (S-POM), complex plant-derived (C-POM), and predominantly microbial-derived organic matter (OM; MOM) and their changes in abundance across soils with several millennia to millions of years of weathering and soil development. We observed that SOM became increasingly stabilized and microbial-derived (lower C : N ratio, increasing δ13C and δ15N) as soil weathering progressed. Peak areas of S-POM (i.e. aliphatic root exudates) did not change over time, while peak areas of C-POM (lignin) and MOM (components of microbial cell walls (amides, quinones, and ketones)) increased over time and depth and were closely related to clay content and pedogenic iron oxides. Hence, our study suggests that with progressing soil development, SOM composition co-varied with changes in the mineral matrix. Our study indicates that structurally more complex OM compounds (C-POM, MOM) play an increasingly important role in soil carbon stabilization mechanisms as the mineral soil matrix becomes increasingly weathered.

show abstract

DRIFTS band areas as measured pool size proxy to reduce parameter uncertainty in soil organic matter models

Cited by 19 publications

References 66 publications

Mineral and Climatic Controls Over Soil Organic Matter Stability Across the Tibetan Alpine Permafrost Region

Mineral and Climatic Controls Over Soil Organic Matter Stability Across the Tibetan Alpine Permafrost Region

Soil organic carbon stocks and quality in small-scale tropical, sub-humid and semi-arid watersheds under shrubland and dry deciduous forest in southwestern India

Soil geochemistry as a driver of soil organic matter composition: insights from a soil chronosequence

Contact Info

Product

Resources

About