Contrasting response of organic carbon mineralisation to iron oxide addition under conditions of low and high microbial biomass in anoxic paddy soil

Anthropogenic elevated nitrogen (N) deposition has an accelerated terrestrial N cycle, shaping soil carbon dynamics and storage through altering soil organic carbon mineralization processes. However, it remains unclear how long-term high N deposition affects soil carbon mineralization in tropical forests. To address this question, we established a long-term N deposition experiment in an N-rich lowland tropical forest of Southern China with N additions such as NH4NO3 of 0 (Control), 50 (Low-N), 100 (Medium-N) and 150 (High-N) kg N ha−1 yr−1, and laboratory incubation experiment, used to explore the response of soil carbon mineralization to the N additions therein. The results showed that 15 years of N additions significantly decreased soil carbon mineralization rates. During the incubation period from the 14th day to 56th day, the average decreases in soil CO2 emission rates were 18%, 33% and 47% in the low-N, medium-N and high-N treatments, respectively, compared with the Control. These negative effects were primarily aroused by the reduced soil microbial biomass and modified microbial functions (e.g., a decrease in bacteria relative abundance), which could be attributed to N-addition-induced soil acidification and potential phosphorus limitation in this forest. We further found that N additions greatly increased soil-dissolved organic carbon (DOC), and there were significantly negative relationships between microbial biomass and soil DOC, indicating that microbial consumption on soil-soluble carbon pool may decrease. These results suggests that long-term N deposition can increase soil carbon stability and benefit carbon sequestration through decreased carbon mineralization in N-rich tropical forests. This study can help us understand how microbes control soil carbon cycling and carbon sink in the tropics under both elevated N deposition and carbon dioxide in the future.

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Land Use Effect on Soil Organic Carbon Stocks, Microbial Biomass and Basal Respiration in Bundelkhand Region of Central India

Agricultural Research ◽

10.1007/s40003-021-00584-6 ◽

2021 ◽

Author(s):

Nongmaithem Raju Singh ◽

Dhiraj Kumar ◽

A. K. Handa ◽

Ram Newaj ◽

Mahendra Prasad ◽

...

Keyword(s):

Land Use ◽

Microbial Biomass ◽

Organic Carbon ◽

Soil Organic Carbon ◽

Central India ◽

Basal Respiration ◽

Carbon Stocks ◽

Soil Organic Carbon Stocks

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Rice straw application with different water regimes stimulate enzymes activity and improve aggregates and their organic carbon contents in a paddy soil

Chemosphere ◽

10.1016/j.chemosphere.2021.129971 ◽

2021 ◽

Vol 274 ◽

pp. 129971

Author(s):

Ibrahim Mohamed ◽

Mohamed A. Bassouny ◽

Mohamed H.H. Abbas ◽

Zhan Ming ◽

Cao Cougui ◽

...

Keyword(s):

Organic Carbon ◽

Rice Straw ◽

Paddy Soil ◽

Water Regimes ◽

Enzymes Activity ◽

Straw Application

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Soil age and soil organic carbon content shape biochemical responses to multiple freeze–thaw events in soils along a postmining agricultural chronosequence

Biogeochemistry ◽

10.1007/s10533-021-00816-5 ◽

2021 ◽

Author(s):

Christoph Rosinger ◽

Michael Bonkowski

Keyword(s):

Microbial Biomass ◽

Organic Carbon ◽

Soil Organic Carbon ◽

Carbon Content ◽

Organic Carbon Content ◽

Freeze Thaw ◽

Biochemical Responses ◽

Microbial Responses ◽

Soil Age ◽

Carbon Losses

AbstractFreeze–thaw (FT) events exert a great physiological stress on the soil microbial community and thus significantly impact soil biogeochemical processes. Studies often show ambiguous and contradicting results, because a multitude of environmental factors affect biogeochemical responses to FT. Thus, a better understanding of the factors driving and regulating microbial responses to FT events is required. Soil chronosequences allow more focused comparisons among soils with initially similar start conditions. We therefore exposed four soils with contrasting organic carbon contents and opposing soil age (i.e., years after restoration) from a postmining agricultural chronosequence to three consecutive FT events and evaluated soil biochgeoemical responses after thawing. The major microbial biomass carbon losses occurred after the first FT event, while microbial biomass N decreased more steadily with subsequent FT cycles. This led to an immediate and lasting decoupling of microbial biomass carbon:nitrogen stoichiometry. After the first FT event, basal respiration and the metabolic quotient (i.e., respiration per microbial biomass unit) were above pre-freezing values and thereafter decreased with subsequent FT cycles, demonstrating initially high dissimilatory carbon losses and less and less microbial metabolic activity with each iterative FT cycle. As a consequence, dissolved organic carbon and total dissolved nitrogen increased in soil solution after the first FT event, while a substantial part of the liberated nitrogen was likely lost through gaseous emissions. Overall, high-carbon soils were more vulnerable to microbial biomass losses than low-carbon soils. Surprisingly, soil age explained more variation in soil chemical and microbial responses than soil organic carbon content. Further studies are needed to dissect the factors associated with soil age and its influence on soil biochemical responses to FT events.

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Color Tuning by Oxide Addition in PEDOT:PSS-Based Electrochromic Devices

Polymers ◽

10.3390/polym11010179 ◽

2019 ◽

Vol 11 (1) ◽

pp. 179 ◽

Cited By ~ 9

Author(s):

Delphin Levasseur ◽

Issam Mjejri ◽

Thomas Rolland ◽

Aline Rougier

Keyword(s):

Thin Films ◽

Iron Oxide ◽

Conducting Polymers ◽

Applied Voltage ◽

Oxide Content ◽

Electrochromic Devices ◽

Careful Evaluation ◽

Pedot Film ◽

Oxide Addition ◽

Dark Blue

Poly(3,4-ethylenedi-oxythiophene) (PEDOT) derivatives conducting polymers are known for their great electrochromic (EC) properties offering a reversible blue switch under an applied voltage. Characterizations of symmetrical EC devices, built on combinations of PEDOT thin films, deposited with a bar coater from commercial inks, and separated by a lithium-based ionic membrane, show highest performance for 800 nm thickness. Tuning of the color is further achieved by mixing the PEDOT film with oxides. Taking, in particular, the example of optically inactive iron oxide Fe2O3, a dark blue to reddish switch, of which intensity depends on the oxide content, is reported. Careful evaluation of the chromaticity parameters L*, a*, and b*, with oxidizing/reducing potentials, evidences a possible monitoring of the bluish tint.

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Effect of iron oxide addition on structural properties of calcium silico phosphate glass/glass-ceramics

Journal of Non-Crystalline Solids ◽

10.1016/j.jnoncrysol.2012.05.034 ◽

2012 ◽

Vol 358 (16) ◽

pp. 1886-1891 ◽

Cited By ~ 16

Author(s):

K. Sharma ◽

M.N. Deo ◽

G.P. Kothiyal

Keyword(s):

Iron Oxide ◽

Structural Properties ◽

Phosphate Glass ◽

Glass Ceramics ◽

Oxide Addition

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Effect of Tillage Systems on Soil Organic Carbon and Soil Quality in a Purple Paddy Soil

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.183-185.1190 ◽

2011 ◽

Vol 183-185 ◽

pp. 1190-1194

Author(s):

Jun Ke Zhang ◽

Qing Ju Hao ◽

Chang Sheng Jiang ◽

Yan Wu

Keyword(s):

Organic Carbon ◽

Soil Quality ◽

Paddy Soil ◽

Conventional Tillage ◽

Water Infiltration ◽

Purple Soil ◽

Tillage Systems ◽

Field Station ◽

No Till ◽

The Impact

The impact of conservation tillage practices on carbon sequestration has been of great interest in recent years. This experiment analyzed the organic carbon status of soils sampled at depth increments from 0 to 60 cm after 20 years in a purple paddy soil. The tillage experiment was established in the Key Field Station for Monitoring of Eco-Environment of Purple Soil of the Ministry of Agriculture of China, located in the farm of Southwest University (30°26′N, 106°26′E), Chongqing. In this paper, five tillage treatments including conventional tillage with rice only system (DP), conventional tillage with rotation of rice and rape system (SL), no-till and ridge culture with rotation of rice and rape system (LM), no-till and plain culture with rotation of rice and rape system (XM) and tillage and ridge culture with rotation of rice and rape system (LF) were selected as research objectives to measure SOC storage and stratification ratio of SOC (CSR). The SOC storage under different tillage systems was calculated based on an equivalent soil mass. The CSR can be used as an indicator of soil quality because surface organic matter is essential to erosion control, water infiltration, and the conservation of nutrients. Results showed that in soil under no-till SOC was concentrated near the surface, while in tilled soil SOC decreased equably with the increase of soil depth. The difference of SOC contents between the five tillage systems was the largest in the top soil and the lowest in the bottom soil. The order of SOC storage was LM (158.52 Mg C•ha-1) >DP (106.74 Mg C•ha-1) >XM (100.11 Mg C•ha-1) >LF (93.11 Mg C•ha-1) >SL (88.59 Mg C•ha-1), LM treatment was significantly higher than the other treatments. The CSR of 0-10/50-60 cm was 2.65, 2.70 and 2.14 under LM, XM and LF treatments, while 1.54 and 1.92 under DP and SL treatments. We considered CSR>2 indicate an improvement in soil quality produced by changing from tillage to no-tillage, as well as changing from plane to ridge. Overall, long-term LM treatment is a valid strategy for increasing SOC storage and improving soil quality in a purple paddy soil in Southwest China.

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