Abstract
Over the last century, researchers and practitioners with diverse backgrounds have articulated the importance of improving soil organic matter (SOM) contents in agricultural soils. More recently, climate change scientists interested in CO2 sinks, and agroecologists interested in ecological intensification have converged on the goal of building SOM stocks in croplands. The challenge is that agriculture itself is responsible for dramatic losses of SOM. When grassland or forest ecosystems are first converted to agriculture, multiple mechanisms result in SOM declines of between 20% and 70%. Two of the most important mechanisms are the reduction in organic matter inputs from roots following the replacement of perennial vegetation with annual crop species, and increases in microbial respiration when tillage breaks open soil aggregates exposing previously protected organic matter. Many agricultural practices such as conservation tillage and integration of cover crops have been shown to achieve some degree of SOM improvement, but in general adoption of these practices falls short of accumulating the SOM stocks maintained by grasslands, forests or other native ecosystems that agriculture replaced. Two of the overarching reasons why native terrestrial ecosystems have achieved greater soil organic matter levels than human agroecosystems are because they direct a greater percentage of productivity belowground in perennial roots, and they do not require frequent soil disturbance. A growing body of research including that presented in this review suggests that developing perennial grain agroecosystems may hold the greatest promise for agriculture to approach the SOM levels that accumulate in native ecosystems. We present calculations that estimate potential soil organic carbon accumulation rates in fields converted from annual to perennial grains of between 0.13 and 1.70 t ha−1 year−1.
Highlights
Soils play a central role in the global carbon cycle, storing two to three times as much carbon in organic forms as there is carbon in the atmosphere [1,2]
Biochar offers a potential exception to the carbon-equilibrium “rule” in which soil organic matter (SOM) accumulation is limited by a site-specific relationship between plant production inputs and microbial respiration loses
Discussions of SOM dynamics in this paper have primarily focused on the importance of perennial vegetation in soil development
Summary
Soils play a central role in the global carbon cycle, storing two to three times as much carbon in organic forms as there is carbon in the atmosphere [1,2]. Agriculture in particular has been responsible for somewhere in the range of 50–78 Pg of C loss to the atmosphere [4,5] This transfer of C represents about 3.8% of global median estimates for total soil organic carbon (SOC) in terrestrial ecosystems [1], and it represents about 5.5 years of global CO2 emissions from fossil fuels at 2014 rates [6]. To assess the potential SOM-building potential of different approaches, it is important to understand the mechanisms driving the depletion of SOM following the conversion of native ecosystems to agriculture. Based on McLauchlan’s three mechanisms of SOM reduction by agriculture, it follows that the native ecosystems preceding agriculture generally maintained relatively high quantities of C inputs into soils, experienced low levels of soil disturbance and maintained year-round vegetative cover which protected against erosion. We will explore further the mechanisms by which agriculture causes reductions in SOM compared to native ecosystems, and we will consider the extent to which different strategies for re-building SOM reverse these mechanisms
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