Changes in soil water retention following biochar amendment

STRUNECKÝ, Otakar, Sowmya SHREEDHAR, Ladislav KOLÁŘ and Anna MAROUŠKOVÁ. Changes in soil water retention following biochar amendment. ENERGY SOURCES PART A-RECOVERY UTILIZATION AND ENVIRONMENTAL EFFECTS. TAYLOR & FRANCIS INC, 2021, Neuveden, APR 2021, p. 1-9, 10 pp. ISSN 1556-7036.

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TY  - JOUR
ID  - 59081
AU  - Strunecký, Otakar - Shreedhar, Sowmya - Kolář, Ladislav - Maroušková, Anna
PY  - 2021
TI  - Changes in soil water retention following biochar amendment
JF  - ENERGY SOURCES PART A-RECOVERY UTILIZATION AND ENVIRONMENTAL EFFECTS
VL  - Neuveden
IS  - APR 2021
SP  - 1-9
EP  - 1-9
PB  - TAYLOR & FRANCIS INC
SN  - 15567036
KW  - Biochar
KW  - climate change
KW  - feedstock
KW  - pyrolysis temperature
KW  - water retention capacity
UR  - https://www.tandfonline.com/doi/full/10.1080/15567036.2021.1916652?scroll=top&needAccess=true
N2  - To mitigate water runoff from arable land, a variety of measures can be applied. One of them is the amendment of highly porous biochar to increase the water retention capacity of soils and store the runoff water. Various types of biochar are made under variable production conditions and amended to soils of different quality in a wide range of quantities. Since reported data show ambiguities due to various feedstock, pyrolysis parameters, soil characteristics, and a highly variable change in water retention capacity (WRC), robust statistical methods were applied to compare the reported data from previous studies. The results revealed that biochar increased WRC by 0.26% t ha−1 of biochar added on average. In terms of WRC, biochar produced at lower pyrolysis temperatures functioned surprisingly better than that produced at higher temperatures, which was confirmed by a decision tree made by J48 algorithm. The increase of WRC was higher with sandy soils, whereas silty and loamy soils did not show a significant increase. Biochar made from easily biodegradable, post-harvest residues such as straw or rice husk showed higher impact than others made from wood that is appreciated for its high porosity. This is a groundbreaking argument for stopping the usage of biochar for energy purposes. The high organic content in soils was the major driver damping the WRC increase. The most effective measure for increasing WRC is the application of 90 t ha−1 biochar, preferably made of an easily biodegradable phytomass that is pyrolyzed at low temperatures. The presented study compares 166 specific combinations of various biochar and soil properties, shows the effectivity of biochar amendments for WTR increment, and reviews the impact of biochar amendment in terms of water retention in agricultural landscapes.
ER  -

Basic information
Original name	Changes in soil water retention following biochar amendment
Authors	STRUNECKÝ, Otakar (703 Slovakia, guarantor, belonging to the institution), Sowmya SHREEDHAR (203 Czech Republic, belonging to the institution), Ladislav KOLÁŘ (203 Czech Republic, belonging to the institution) and Anna MAROUŠKOVÁ (203 Czech Republic, belonging to the institution).
Edition	ENERGY SOURCES PART A-RECOVERY UTILIZATION AND ENVIRONMENTAL EFFECTS, TAYLOR & FRANCIS INC, 2021, 1556-7036.

Other information
Original language	English
Type of outcome	Article in a journal
Field of Study	20800 2.8 Environmental biotechnology
Country of publisher	United States of America
Confidentiality degree	is not subject to a state or trade secret
WWW	URL
RIV identification code	RIV/75081431:_____/21:00002112
Organization unit	Institute of Technology and Business in České Budějovice
UT WoS	000640581200001
Keywords in English	Biochar; climate change; feedstock; pyrolysis temperature; water retention capacity
Tags	PRI_a, RIV21, WOS
Changed by	Changed by: Mgr. Nikola Petříková, učo 28324. Changed: 22/7/2021 12:37.

Abstract

To mitigate water runoff from arable land, a variety of measures can be applied. One of them is the amendment of highly porous biochar to increase the water retention capacity of soils and store the runoff water. Various types of biochar are made under variable production conditions and amended to soils of different quality in a wide range of quantities. Since reported data show ambiguities due to various feedstock, pyrolysis parameters, soil characteristics, and a highly variable change in water retention capacity (WRC), robust statistical methods were applied to compare the reported data from previous studies. The results revealed that biochar increased WRC by 0.26% t ha−1 of biochar added on average. In terms of WRC, biochar produced at lower pyrolysis temperatures functioned surprisingly better than that produced at higher temperatures, which was confirmed by a decision tree made by J48 algorithm. The increase of WRC was higher with sandy soils, whereas silty and loamy soils did not show a significant increase. Biochar made from easily biodegradable, post-harvest residues such as straw or rice husk showed higher impact than others made from wood that is appreciated for its high porosity. This is a groundbreaking argument for stopping the usage of biochar for energy purposes. The high organic content in soils was the major driver damping the WRC increase. The most effective measure for increasing WRC is the application of 90 t ha−1 biochar, preferably made of an easily biodegradable phytomass that is pyrolyzed at low temperatures. The presented study compares 166 specific combinations of various biochar and soil properties, shows the effectivity of biochar amendments for WTR increment, and reviews the impact of biochar amendment in terms of water retention in agricultural landscapes.

PrintDisplayed: 10/6/2024 22:08

Changes in soil water retention following biochar amendment

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