C:N:P stoichiometry associated with biochar in forest soils at historical charcoal production sites in Poland

Biochar amendment leads to change of physical, chemical and biochemical properties of soil. The aim of our research was to determine C/N/P stoichiometry of soils with biochar in pine forest in places of historical charcoal production. The research was carried out in the Manowo Forest District, north...

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Published inGeoderma Regional Vol. 28; p. e00482
Main Authors Lasota, Jarosław, Babiak, Tomasz, Błońska, Ewa
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.03.2022
Subjects
biochar
carbon
carbon sequestration
coniferous forests
Ecological stoichiometry
Enzyme activity
nitrogen
nutrient availability
Nutrients
phosphorus
Pine forest
Podzols
Poland
soil enzymes
stoichiometry
wood
Poland
Pine forest
Nutrients
Enzyme activity
Ecological stoichiometry
Podzols
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Abstract Biochar amendment leads to change of physical, chemical and biochemical properties of soil. The aim of our research was to determine C/N/P stoichiometry of soils with biochar in pine forest in places of historical charcoal production. The research was carried out in the Manowo Forest District, northern Poland (54°08′52″N; 16°27′53″E). The research was carried out in an area where relict charcoal hearths are abundant. The burning of charcoal in this area took place about 200–250 years ago. Pine wood was used in relict charcoal hearths. The samples for analysis were taken from relict charcoal hearths and in the immediate vicinity (background). We determined the enzymatic activity and we recorded the content of C, N and P in testing samples. We also calculated the C/N/P stoichiometry for samples and we used soil enzyme activity stoichiometry for reflects the nutrient availability. Our research confirmed the role of biochar in shaping the C/N/P stoichiometry in forest soils. Soils with biochar were characterized by wider stoichiometry and significantly higher C and P content compared to the control soils. The enrichment of the soil with biochar resulted in a significant increase in the activity of enzymes involved in the carbon cycle (β-glucosidase and β-D-cellobiosidase), nitrogen (N-acetyl-β-D-glucosaminidase) and phosphorus (phosphatase). The enzyme stoichiometry confirmed limited availability of nutrients, especially nitrogen. Biochar in historical charcoal production sites increased total carbon stocks in temperate pine forests. This implied that relict charcoal hearths can significantly promote the carbon sequestration capacity. •Adding a biochar changes the C/N/P stoichiometry of the soils as a result of providing C and P.•The enrichment of the soil with biochar resulted in an increase in the activity of enzymes.•Microbial N acguisition is limited and soil enzyme activity stoichiometry reflects the nutrient limitations.•Relict charcoal hearths can significantly promote the carbon sequestration capacity.
AbstractList Biochar amendment leads to change of physical, chemical and biochemical properties of soil. The aim of our research was to determine C/N/P stoichiometry of soils with biochar in pine forest in places of historical charcoal production. The research was carried out in the Manowo Forest District, northern Poland (54°08′52″N; 16°27′53″E). The research was carried out in an area where relict charcoal hearths are abundant. The burning of charcoal in this area took place about 200–250 years ago. Pine wood was used in relict charcoal hearths. The samples for analysis were taken from relict charcoal hearths and in the immediate vicinity (background). We determined the enzymatic activity and we recorded the content of C, N and P in testing samples. We also calculated the C/N/P stoichiometry for samples and we used soil enzyme activity stoichiometry for reflects the nutrient availability. Our research confirmed the role of biochar in shaping the C/N/P stoichiometry in forest soils. Soils with biochar were characterized by wider stoichiometry and significantly higher C and P content compared to the control soils. The enrichment of the soil with biochar resulted in a significant increase in the activity of enzymes involved in the carbon cycle (β-glucosidase and β-D-cellobiosidase), nitrogen (N-acetyl-β-D-glucosaminidase) and phosphorus (phosphatase). The enzyme stoichiometry confirmed limited availability of nutrients, especially nitrogen. Biochar in historical charcoal production sites increased total carbon stocks in temperate pine forests. This implied that relict charcoal hearths can significantly promote the carbon sequestration capacity.
Biochar amendment leads to change of physical, chemical and biochemical properties of soil. The aim of our research was to determine C/N/P stoichiometry of soils with biochar in pine forest in places of historical charcoal production. The research was carried out in the Manowo Forest District, northern Poland (54°08′52″N; 16°27′53″E). The research was carried out in an area where relict charcoal hearths are abundant. The burning of charcoal in this area took place about 200–250 years ago. Pine wood was used in relict charcoal hearths. The samples for analysis were taken from relict charcoal hearths and in the immediate vicinity (background). We determined the enzymatic activity and we recorded the content of C, N and P in testing samples. We also calculated the C/N/P stoichiometry for samples and we used soil enzyme activity stoichiometry for reflects the nutrient availability. Our research confirmed the role of biochar in shaping the C/N/P stoichiometry in forest soils. Soils with biochar were characterized by wider stoichiometry and significantly higher C and P content compared to the control soils. The enrichment of the soil with biochar resulted in a significant increase in the activity of enzymes involved in the carbon cycle (β-glucosidase and β-D-cellobiosidase), nitrogen (N-acetyl-β-D-glucosaminidase) and phosphorus (phosphatase). The enzyme stoichiometry confirmed limited availability of nutrients, especially nitrogen. Biochar in historical charcoal production sites increased total carbon stocks in temperate pine forests. This implied that relict charcoal hearths can significantly promote the carbon sequestration capacity. •Adding a biochar changes the C/N/P stoichiometry of the soils as a result of providing C and P.•The enrichment of the soil with biochar resulted in an increase in the activity of enzymes.•Microbial N acguisition is limited and soil enzyme activity stoichiometry reflects the nutrient limitations.•Relict charcoal hearths can significantly promote the carbon sequestration capacity.
ArticleNumber e00482
Author Lasota, Jarosław
Błońska, Ewa
Babiak, Tomasz
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  surname: Lasota
  fullname: Lasota, Jarosław
  organization: University of Agriculture in Krakow, Faculty of Forestry, Department of Forest Soil Science, Al. 29 Listopada 46, 31-425 Kraków, Poland
– sequence: 2
  givenname: Tomasz
  surname: Babiak
  fullname: Babiak, Tomasz
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  givenname: Ewa
  surname: Błońska
  fullname: Błońska, Ewa
  email: eblonska@ar.krakow.pl
  organization: University of Agriculture in Krakow, Faculty of Forestry, Department of Forest Soil Science, Al. 29 Listopada 46, 31-425 Kraków, Poland
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Snippet Biochar amendment leads to change of physical, chemical and biochemical properties of soil. The aim of our research was to determine C/N/P stoichiometry of...
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SubjectTerms biochar
carbon
carbon sequestration
coniferous forests
Ecological stoichiometry
Enzyme activity
nitrogen
nutrient availability
Nutrients
phosphorus
Pine forest
Podzols
Poland
soil enzymes
stoichiometry
wood
Title C:N:P stoichiometry associated with biochar in forest soils at historical charcoal production sites in Poland
URI https://dx.doi.org/10.1016/j.geodrs.2022.e00482
https://www.proquest.com/docview/2636713570
Volume 28
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