Tristram O. West scite author profile

tices include, but are not limited to, reducing tillage intensity, decreasing or ceasing the fallow period, using Changes in agricultural management can potentially increase the a winter cover crop, changing from monoculture to rotaaccumulation rate of soil organic C (SOC), thereby sequestering CO 2 from the atmosphere. This study was conducted to quantify potential tion cropping, or altering soil inputs to increase primary soil C sequestration rates for different crops in response to decreasing production (e.g., fertilizers, pesticides, and irrigation). tillage intensity or enhancing rotation complexity, and to estimate the Implementing practices that sequester C can reverse the duration of time over which sequestration may occur. Analyses of C loss of SOC that may have occurred under intensive sequestration rates were completed using a global database of 67 longcultivation thereby increasing SOC to a new equilibrium term agricultural experiments, consisting of 276 paired treatments.

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Soil Organic Carbon Sequestration by Tillage and Crop Rotation: A Global Data Analysis

West¹,

Post²

2002

425

546

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A synthesis of carbon sequestration, carbon emissions, and net carbon flux in agriculture: comparing tillage practices in the United States

West

Marland

2002

Agriculture, Ecosystems & Environment

1,189

528

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Toward more realistic projections of soil carbon dynamics by Earth system models

Luo

Ahlström

Allison

et al. 2016

Global Biogeochemical Cycles

397

360

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Soil carbon (C) is a critical component of Earth system models (ESMs), and its diverse representations are a major source of the large spread across models in the terrestrial C sink from the third to fifth assessment reports of the Intergovernmental Panel on Climate Change (IPCC). Improving soil C projections is of a high priority for Earth system modeling in the future IPCC and other assessments. To achieve this goal, we suggest that (1) model structures should reflect real-world processes, (2) parameters should be calibrated to match model outputs with observations, and (3) external forcing variables should accurately prescribe the environmental conditions that soils experience. First, most soil C cycle models simulate C input from litter production and C release through decomposition. The latter process has traditionally been represented by first-order decay functions, regulated primarily by temperature, moisture, litter quality, and soil texture. While this formulation well captures macroscopic soil organic C (SOC) dynamics, better understanding is needed of their underlying mechanisms as related to microbial processes, depth-dependent environmental controls, and other processes that strongly affect soil C dynamics. Second, incomplete use of observations in model parameterization is a major cause of bias in soil C projections from ESMs. Optimal parameter calibration with both pool-and flux-based data sets through data assimilation is LUO ET AL.SOIL CARBON MODELING 40 PUBLICATIONS

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North American Carbon Program (NACP) regional interim synthesis: Terrestrial biospheric model intercomparison

Huntzinger

Post

Wei

et al. 2012

Ecological Modelling

227

234

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Understanding of carbon exchange between terrestrial ecosystems and the atmosphere can be improved through direct observations and experiments, as well as through modeling activities. Terrestrial biosphere models (TBMs) have become an integral tool for extrapolating local observations and understanding to much larger terrestrial regions. Although models vary in their specific goals and approaches, their central role within carbon cycle science is to provide a better understanding of the mechanisms currently controlling carbon exchange. Recently, the North American Carbon Program (NACP) organized several interim-synthesis activities to evaluate and inter-compare models and observations at local to continental scales for the years 2000-2005. Here, we compare the results from the TBMs collected as part of the regional and continental interim-synthesis (RCIS) activities. The primary objective of this work is to synthesize and compare the 19 participating TBMs to assess current understanding of the terrestrial carbon cycle in North America. Thus, the RCIS focuses on model simulations available from analyses that have been completed by ongoing NACP projects and other recently published studies. The TBM flux estimates are compared and evaluated over different spatial (1 degrees X 1 degrees and spatially aggregated to different regions) and temporal (monthly and annually) scales. The range in model estimates of net ecosystem productivity (NEP) for North America is much narrower than estimates of productivity or respiration, with estimates of NEP varying between 0.7 and 2.2 PgC yr(-1), while gross primary productivity and heterotrophic respiration vary between 12.2 and 32.9 PgCyr(-1) and 5.6 and 13.2 PgC yr(-1), respectively. The range in estimates from the models appears to be driven by a combination of factors, including the representation of photosynthesis, the source and of environmental driver data and the temporal variability of those data, as well as whether nutrient limitation is considered in soil carbon decomposition. The disagreement in current estimates of carbon flux across North America, including whether North America is a net biospheric carbon source or sink, highlights the need for further analysis through the use of model runs following a common simulation protocol, in order to isolate the influences of model formulation, structure, and assumptions on flux estimates. (C) 2012 Elsevier B.V. All rights reserved

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Tristram O. West

Soil Organic Carbon Sequestration Rates by Tillage and Crop Rotation

Soil Organic Carbon Sequestration by Tillage and Crop Rotation: A Global Data Analysis

A synthesis of carbon sequestration, carbon emissions, and net carbon flux in agriculture: comparing tillage practices in the United States

Toward more realistic projections of soil carbon dynamics by Earth system models

North American Carbon Program (NACP) regional interim synthesis: Terrestrial biospheric model intercomparison

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