Detail publikačního výsledku

The impact of single and combined amendment of elemental sulphur and graphene oxide on soil microbiome and nutrient transformation activities

HAMMERSCHMIEDT, T.; HOLÁTKO, J.; BYTEŠNÍKOVÁ, Z.; ŠKARPA, P.; RICHTERA, L.; KINTL, A.; PEKÁRKOVÁ, J.; KUČERÍK, J.; JASKULSKA, I.; RADZIEMSKA, M.; VALOVÁ, R.; MALÍČEK, O.; BRTNICKÝ, M.

Originální název

The impact of single and combined amendment of elemental sulphur and graphene oxide on soil microbiome and nutrient transformation activities

Anglický název

The impact of single and combined amendment of elemental sulphur and graphene oxide on soil microbiome and nutrient transformation activities

Druh

Článek Scopus

Originální abstrakt

Background: Sulphur (S) deficiency has emerged in recent years in European soils due to the decreased occurrence of acid rains. Elemental sulphur (S0) is highly beneficial as a source of S in agriculture, but it must be oxidized to a plant-accessible form. Micro- or nano-formulated S0 may undergo accelerated transformation, as the oxidation rate of S0 indirectly depends on particle size. Graphene oxide (GO) is a 2D-carbon-based nanomaterial with benefits as soil amendment, which could modulate the processes of S0 oxidation. Micro-and nano-sized composites, comprised of S0 and GO, were tested as soil amendments in a pot experiment with unplanted soil to assess their effects on soil microbial biomass, activity, and transformation to sulphates. Fourteen different variants were tested, based on solely added GO, solely added micro- or nano-sized S0 (each in three different doses) and on a combination of all S0 doses with GO. Results: Compared to unamended soil, nano-S0 and nano-S0+GO increased soil pH(CaCl2). Micro-S0 (at a dose 4 g kg−1) increased soil pH(CaCl2), whereas micro-S0+GO (at a dose 4 g kg−1) decreased soil pH(CaCl2). The total bacterial and ammonium oxidizer microbial abundance decreased due to micro-S0 and nano-S0 amendment, with an indirect dependence on the amended dose. This trend was alleviated by the co-application of GO. Urease activity showed a distinct response to micro-S0+GO (decreased value) and nano-S0+GO amendment (increased value). Arylsulfatase was enhanced by micro-S0+GO, while sulphur reducing bacteria (dsr) increased proliferation due to high micro-S0 and nano-S0, and co-amendment of both with GO. In comparison to nano-S0, the amendment of micro-S0+GO more increased soluble sulphur content more significantly. Conclusions: Under the conditions of this soil experiment, graphene oxide exhibited a significant effect on the process of sulphur oxidation.

Anglický abstrakt

Background: Sulphur (S) deficiency has emerged in recent years in European soils due to the decreased occurrence of acid rains. Elemental sulphur (S0) is highly beneficial as a source of S in agriculture, but it must be oxidized to a plant-accessible form. Micro- or nano-formulated S0 may undergo accelerated transformation, as the oxidation rate of S0 indirectly depends on particle size. Graphene oxide (GO) is a 2D-carbon-based nanomaterial with benefits as soil amendment, which could modulate the processes of S0 oxidation. Micro-and nano-sized composites, comprised of S0 and GO, were tested as soil amendments in a pot experiment with unplanted soil to assess their effects on soil microbial biomass, activity, and transformation to sulphates. Fourteen different variants were tested, based on solely added GO, solely added micro- or nano-sized S0 (each in three different doses) and on a combination of all S0 doses with GO. Results: Compared to unamended soil, nano-S0 and nano-S0+GO increased soil pH(CaCl2). Micro-S0 (at a dose 4 g kg−1) increased soil pH(CaCl2), whereas micro-S0+GO (at a dose 4 g kg−1) decreased soil pH(CaCl2). The total bacterial and ammonium oxidizer microbial abundance decreased due to micro-S0 and nano-S0 amendment, with an indirect dependence on the amended dose. This trend was alleviated by the co-application of GO. Urease activity showed a distinct response to micro-S0+GO (decreased value) and nano-S0+GO amendment (increased value). Arylsulfatase was enhanced by micro-S0+GO, while sulphur reducing bacteria (dsr) increased proliferation due to high micro-S0 and nano-S0, and co-amendment of both with GO. In comparison to nano-S0, the amendment of micro-S0+GO more increased soluble sulphur content more significantly. Conclusions: Under the conditions of this soil experiment, graphene oxide exhibited a significant effect on the process of sulphur oxidation.

Klíčová slova

Bacteria; Fungi; Nanoparticles; Oxidation; Soil enzymes; Soil sulphate

Klíčová slova v angličtině

Bacteria; Fungi; Nanoparticles; Oxidation; Soil enzymes; Soil sulphate

Autoři

HAMMERSCHMIEDT, T.; HOLÁTKO, J.; BYTEŠNÍKOVÁ, Z.; ŠKARPA, P.; RICHTERA, L.; KINTL, A.; PEKÁRKOVÁ, J.; KUČERÍK, J.; JASKULSKA, I.; RADZIEMSKA, M.; VALOVÁ, R.; MALÍČEK, O.; BRTNICKÝ, M.

Rok RIV

2025

Vydáno

15.10.2024

Nakladatel

Elsevier Ltd

Místo

Amstrdam

ISSN

2405-8440

Periodikum

Heliyon

Svazek

10

Číslo

19

Stát

Spojené království Velké Británie a Severního Irska

Strany od

1

Strany do

13

Strany počet

13

URL

https://www.sciencedirect.com/science/article/pii/S2405844024144702?pes=vor&utm_source=scopus&getft_integrator=scopus

Plný text v Digitální knihovně

http://hdl.handle.net/11012/250739

BibTex

@article{BUT193992,
  author="Tereza {Hammerschmiedt} and Jiří {Holátko} and Zuzana {Bytešníková} and Petr {Škarpa} and Lukáš {Richtera} and Antonín {Kintl} and Jana {Pekárková} and Jiří {Kučerík} and Iwona {Jaskulska} and Maja {Radziemska} and Radmila {Valová} and Ondřej {Malíček} and Martin {Brtnický}",
  title="The impact of single and combined amendment of elemental sulphur and graphene oxide on soil microbiome and nutrient transformation activities",
  journal="Heliyon",
  year="2024",
  volume="10",
  number="19",
  pages="1--13",
  doi="10.1016/j.heliyon.2024.e38439",
  url="https://www.sciencedirect.com/science/article/pii/S2405844024144702?pes=vor&utm_source=scopus&getft_integrator=scopus"
}

Dokumenty

1-s2.0-S2405844024144702-main