No‐Tillage and Soil‐Profile Carbon Sequestration: An On‐Farm Assessment

Blanco‐Canqui, Humberto; Lal, Rattan

doi:10.2136/sssaj2007.0233

Cited by 458 publications

(269 citation statements)

References 29 publications

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“…Information on the effect of maize stover removal under no-till management on soil C from long-term studies has not been available to date [21]. Most of the research on SOC in agricultural production systems focused on C in the 0 to 30 cm depth [22][23][24][25][26][27]. A few studies in which soil sampling has been conducted at greater depths indicate that production agriculture affects soil C deeper in the soil profile [28,29].…”

Section: Introductionmentioning

confidence: 99%

Soil Carbon Sequestration by Switchgrass and No-Till Maize Grown for Bioenergy

et al. 2012

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Net benefits of bioenergy crops, including maize and perennial grasses such as switchgrass, are a function of several factors including the soil organic carbon (SOC) sequestered by these crops. Life cycle assessments (LCA) for bioenergy crops have been conducted using models in which SOC information is usually from the top 30 to 40 cm. Information on the effects of crop management practices on SOC has been limited so LCA models have largely not included any management practice effects. In the first 9 years of a long-term C sequestration study in eastern Nebraska, USA, switchgrass and maize with best management practices had average annual increases in SOC per hectare that exceed 2 Mg Cyear −1 (7.3 Mg CO 2 year −1 ) for the 0 to 150 soil depth. For both switchgrass and maize, over 50 % of the increase in SOC was below the 30 cm depth. SOC sequestration by switchgrass was twofold to fourfold greater than that used in models to date which also assumed no SOC sequestration by maize. The results indicate that N fertilizer rates and harvest management regimes can affect the magnitude of SOC sequestration. The use of uniform soil C effects for bioenergy crops from sampling depths of 30 to 40 cm across agro-ecoregions for large scale LCA is questionable.

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Section: Introductionmentioning

confidence: 99%

Soil Carbon Sequestration by Switchgrass and No-Till Maize Grown for Bioenergy

et al. 2012

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“…As noted earlier, there have been a growing number of authors in recent years who have pointed out limitations to assigning NT as a universal panacea to mitigate climate change through the removal of atmospheric CO 2 into long-term storage in the soil (Gregorich et al 2007;Blanco-Canqui and Lal 2008;Hammons 2009;Powlson et al 2014;VandenBygaart 2016). Four reasons include (1) the stratification of SOC in the profile of NT soils and its concentration at the surface to 20 cm (8 in) relative to PT soils (Powlson et al 2014), with the implication that SOC is merely redistributed, rather than accumulated, over time; (2) climatic limitations, such as the cool, moist region of eastern Canada (Gregorich et al 2007); (3) the definition of "no-till" itself, which can include occasional tillage (VandenBygaart 2016); and (4) a high spatial variability at the farm scale (Blanco-Canqui and Lal 2008).…”

Section: Resultsmentioning

confidence: 99%

“…There is a large body of evidence in the literature that NT management results in an increase in surface (0 to 20 cm [0 to 8 in]) SOC under many soil types and climatic conditions, though the effectiveness of NT management over PT to sequester C has been hotly debated (Gregorich et al 2007;Blanco-Canqui and Lal 2008;Hammons 2009;Powlson et al 2014;VandenBygaart 2016). The concerns have been addressed in part by two meta-analyses comparing PT to NT, where NT was found to sequester significantly more C than PT to 30 cm (12 in) (Angers and Eriksen-Hamel 2008) and to 160 cm (63 in) (Mangalassery et al 2015).…”

mentioning

confidence: 99%

Modeling soil organic carbon in corn ( Zea mays L.)-based systems in Ohio under climate change

Maas¹,

Lal²,

Coleman³

et al. 2017

Journal of Soil and Water Conservation

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“…Studies supporting the positive effects of NT on soil C (Lal, 2004) have been countered by studies that report no net C sequestration when compared to CT (Blanco-Canqui and Lal, 2008). There have also been studies that show both CT and NT systems may lead to soil C losses (Kumar et al, 2012) even though these studies were conducted under diverse field conditions (e.g.…”

Section: Introductionmentioning

confidence: 99%

Evaluating the impact of soil conservation measures on soil organic carbon at the farm scale

Pezzuolo

Dumont

Sartori

et al. 2017

Computers and Electronics in Agriculture

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a b s t r a c tNo-tillage (NT) is considered the least invasive conservation agriculture technique and has shown to be the effective in increasing soil C stocks, and reducing losses compared to others tillage systems. In Italy, the Veneto Region was the first to establish a subsidies scheme aimed at promoting the adoption of NT practices. This program encourages farmers to perform direct seeding, alternate autumn and winter crops and maintain soil cover throughout the year by leaving crop residues or sowing cover crops.The goals of this study were to: (i) compare the CO 2 emission and soil C sequestration patterns of agricultural soils under CT and NT management practices in the Veneto region and (ii) analyse the potential mid-term benefits (2010-2025) of NT management in terms of soil organic C dynamics and CO 2 balance. Agronomic data and soil organic carbon levels were measured from 2010 to 2014 in eight farms in the Veneto region that had adopted CT and NT techniques. Field measurements were used to calibrate first and then validate the SALUS model to compare the mid-term impact of CT and NT practices using climate projections. SOC carbon pools in the model were initialized using the procedure described in Basso et al. (2011c). This is the first study to employ a model using such an extensive dataset at the farm level to assess the CT and NT strategies within this region.Results of this research will assist farmers and policy makers in the region to define the tillage systems most suited to improve soil C stocks and thereby minimize CO 2 emissions from agricultural soils. Overall, simulations indicated that SOC stocks can decrease under both CT and NT regimes, however SOC oxidation rates were substantially lower under NT. Critically, the greatest reduction in CO 2 emission was observed when NT was adopted in soil with high levels of SOM. This highlights the benefits of NT adoption in terms of soil fertility preservation and CO 2 emissions mitigation.

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No‐Tillage and Soil‐Profile Carbon Sequestration: An On‐Farm Assessment

Cited by 458 publications

References 29 publications

Soil Carbon Sequestration by Switchgrass and No-Till Maize Grown for Bioenergy

Soil Carbon Sequestration by Switchgrass and No-Till Maize Grown for Bioenergy

Modeling soil organic carbon in corn ( Zea mays L.)-based systems in Ohio under climate change

Evaluating the impact of soil conservation measures on soil organic carbon at the farm scale

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