Long-term trends in fertility of soils under continuous cultivation and cereal cropping in southern Queensland. IX. Simulation of soil carbon and nitrogen pools using CENTURY model

Cultivation and cropping of soils results in a decline in soil organic carbon and soil nitrogen, and can lead to reduced crop yields. The CENTURY model was used to simulate the effects of continuous cultivation and cereal cropping on total soil organic matter (C and N), carbon pools, nitrogen mineralisation, and crop yield from 6 locations in southern Queensland. The model was calibrated for each replicate from the original datasets, allowing comparisons for each replicate rather than site averages. The CENTURY model was able to satisfactorily predict the impact of long-term cultivation and cereal cropping on total organic carbon, but was less successful in simulating the different fractions and nitrogen mineralisation. The model firstly over-predicted the initial (pre-cropping) soil carbon and nitrogen concentration of the sites. To account for the unique shrinking and swelling characteristics of the Vertosol soils, the default annual decomposition rates of the slow and passive carbon pools were doubled, and then the model accurately predicted initial conditions. The ability of the model to predict carbon pool fractions varied, demonstrating the difficulty inherent in predicting the size of these conceptual pools. The strength of the model lies in the ability to closely predict the starting soil organic matter conditions, and the ability to predict the impact of clearing, cultivation, fertiliser application, and continuous cropping on total soil carbon and nitrogen.

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The influence of short-term and long-term warming on physical soil carbon pools

10.5194/egusphere-egu2020-18383 ◽

2020 ◽

Author(s):

Moritz Mohrlok ◽

Victoria Martin ◽

Niel Verbrigghe ◽

Lucia Fuchslueger ◽

Christopher Poeplau ◽

...

Keyword(s):

Organic Matter ◽

Soil Carbon ◽

Carbon Pool ◽

Carbon Pools ◽

Similar Response ◽

Turnover Rates ◽

Short Term ◽

Microbial Decomposition ◽

Carbon And Nitrogen

Soils store more carbon than the atmosphere and total land plant biomass combined. Soil organic matter (SOM) can be classified into different physical pools characterized by their degree of protection and turnover rates. Usually, these pools are isolated by dividing soils in different water-stable aggregate size classes and, inside these classes, SOM fractions with differing densities and properties: Stable mineral-associated organic matter (MOM) and labile particulate organic matter (POM). Increasing temperatures are known to initially enhance microbial decomposition rates, releasing C from soils which could further accelerate climate change. The magnitude of this feedback depends on which C pool is affected the most by increased decomposition. Since MOM, thought to be the best protected carbon pool, holds most of the soil C, losses from this pool would potentially have the biggest impact on global climate. Experimental results are inconclusive so far, as most studies are based on short-term field warming (years rather than decades), leaving the ecosystem response to decades to century of warming uncertain.We made use of a geothermal warming platform in Iceland (ForHot; https://forhot.is/) to compare the effect of short-term (STW, 5-8 years) and long-term (LTW, more than 50 years) warming on soil organic carbon and nitrogen (SOC, SON) and its carbon and nitrogen isotope composition (&#948;13C and &#948;15N) in soil aggregates of different sizes in a subarctic grassland. OM fractions were isolated via density fractionation and ultrasonication both in macro- and microaggregates: Inter-aggregate free POM (fPOM), POM occluded within aggregates (iPOM) and MOM.MOM, containing most of the SOC and SON, showed a similar response to warming for both macro- and microaggregates. Compared to LTW plots, STW plots overall had higher C and N stocks. But warming reduced the carbon content more strongly in STW plot than in LTW plots. &#948;13C of MOM soil increased with temperature on the STW sites, indicating higher overall SOM turnover rates at higher temperatures, in line with the higher SOC losses. For LTW, &#948;13C decreased with warming except for the most extreme treatment (+16&#176;C). Warming duration had no impact on iPOM-C. fPOM-C decreased in STW sites with increasing temperature, while it increased on the LTW sites.Overall our results demonstrate warming-induced C losses from the MOM-C-pool, thought to be most stable soil carbon pool. Thus, warming stimulated microbes to decompose both labile fPOM and more stable MOM. After decades of warming, C losses are less pronounced compared to the short-term warmed plots, pointing to a replenishment of the carbon pools at higher temperatures in the long-term. This might be explained by adaptations of the primary productivity and/or substrate-limitation of microbial growth.&#160;

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Soil carbon and nitrogen fractions in the soil profile and their response to long-term nitrogen fertilization in a wheat field

CATENA ◽

10.1016/j.catena.2015.06.018 ◽

2015 ◽

Vol 135 ◽

pp. 38-46 ◽

Cited By ~ 32

Author(s):

Yangquanwei Zhong ◽

Weiming Yan ◽

Zhouping Shangguan

Keyword(s):

Soil Carbon ◽

Nitrogen Fertilization ◽

Soil Profile ◽

Wheat Field ◽

Carbon And Nitrogen ◽

Nitrogen Fractions ◽

Soil Carbon And Nitrogen

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Apparent Stability and Subtle Change in Surface and Subsurface Soil Carbon and Nitrogen under a Long-Term Fertilizer Gradient

Soil Science Society of America Journal ◽

10.2136/sssaj2016.09.0299 ◽

2017 ◽

Vol 81 (2) ◽

pp. 310-321 ◽

Cited By ~ 6

Author(s):

Sarah M. Collier ◽

Matthew D. Ruark ◽

Mack R. Naber ◽

Todd W. Andraski ◽

Michael D. Casler

Keyword(s):

Soil Carbon ◽

Subtle Change ◽

Carbon And Nitrogen ◽

Soil Carbon And Nitrogen ◽

Subsurface Soil ◽

Apparent Stability

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Labile soil carbon and nitrogen fractions under short and long-term integrated crop–livestock agroecosystems

Soil Research ◽

10.1071/sr21038 ◽

2021 ◽

Author(s):

Jashanjeet Kaur Dhaliwal ◽

Kavya Laxmisagra Sagar ◽

Jemila Chellappa ◽

Udayakumar Sekaran ◽

Sandeep Kumar

Keyword(s):

Soil Carbon ◽

Carbon And Nitrogen ◽

Nitrogen Fractions ◽

Soil Carbon And Nitrogen ◽

Short And Long Term

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The impact of porosity on organic matter cycling in a two-dimensional porous medium

10.5194/egusphere-egu21-9432 ◽

2021 ◽

Author(s):

Hanbang Zou ◽

Pelle Ohlsson ◽

Edith Hammer

Keyword(s):

Porous Medium ◽

Organic Matter ◽

Carbon Sequestration ◽

Soil Carbon ◽

Pore Network ◽

Pore Scale ◽

Decomposition Of Organic Matter ◽

Organic Matter Cycling ◽

The Impact

Carbon sequestration has been a popular research topic in recent years as the rapid elevation of carbon emission has significantly impacted our climate. Apart from carbon capture and storage in e.g. oil reservoirs, soil carbon sequestration offers a long term and safe solution for the environment and human beings. The net soil carbon budget is determined by the balance between terrestrial ecosystem sink and sources of respiration to atmospheric carbon dioxide. Carbon can be long term stored as organic matters in the soil whereas it can be released from the decomposition of organic matter. The complex pore networks in the soil are believed to be able to "protect" microbial-derived organic matter from decomposition. Therefore, it is important to understand how soil structure impacts organic matter cycling at the pore scale. However, there are limited experimental studies on understanding the mechanism of physical stabilization of organic matter. Hence, my project plan is to create a heterogeneous microfluidic porous microenvironment to mimic the complex soil pore network which allows us to investigate the ability of organisms to access spaces starting from an initial ecophysiological precondition to changes of spatial accessibility mediated by interactions with the microbial community.Microfluidics is a powerful tool that enables studies of fundamental physics, rapid measurements and real-time visualisation in a complex spatial microstructure that can be designed and controlled. Many complex processes can now be visualized enabled by the development of microfluidics and photolithography, such as microbial dynamics in pore-scale soil systems and pore network modification mimicking different soil environments &#8211; earlier considered impossible to achieve experimentally. The microfluidic channel used in this project contains a random distribution of cylindrical pillars of different sizes so as to mimic the variations found in real soil. The randomness in the design creates various spatial availability for microbes (preferential flow paths with dead-end or continuous flow) as an invasion of liquids proceeds into the pore with the lowest capillary entry pressure. In order to study the impact of different porosity in isolation of varying heterogeneity of the porous medium, different pore size chips that use the same randomly generated pore network is created. Those chips have the same location of the pillars, but the relative size of each pillar is scaled. The experiments will be carried out using sterile cultures of fluorescent bacteria, fungi and protists, synthetic communities of combinations of these, or a whole soil community inoculum. We will quantify the consumption of organic matter from the different areas via fluorescent substrates, and the bio-/necromass produced. We hypothesise that lower porosity will reduce the net decomposition of organic matter as the narrower pore throat limits the access, and that net decomposition rate at the main preferential path will be higher than inside branches

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