Unexpected microbial metabolic responses to elevated temperatures and nitrogen addition in subarctic soils under different land uses

authored by

Julia Schroeder, Tino Peplau, Edward Gregorich, Christoph C. Tebbe, Christopher Poeplau

Abstract

Subarctic regions are particularly affected by global warming. As vegetation periods lengthen, boreal forests could gradually be converted into agricultural land. How land use alters the susceptibility of soil organic matter decomposition to rising temperatures or how changes in nutrient availability, such as nitrogen (N) fertilisation, affect carbon (C) cycling is unknown. Microbial carbon use efficiency (CUE) defines how much of the decomposed soil organic carbon is directed to growth or lost to the atmosphere. Here, we investigated the response of CUE (24 h) and soil organic matter decomposition (50 days) to + 10 °C warming and N addition in three subarctic soils derived from paired plots (forest, grassland, cropland) in the Yukon, Canada. Contrary to our literature-based expectations, boreal forest soils did not demonstrate the most sensitive response to warming and N addition. Temperature sensitivity was not affected by land-use type. In contrast to a generally assumed decline, short-term warming increased CUE by + 30%, which was positively correlated with microbial growth. N addition reduced overall CUE by − 7%, in contrast to the expectation that CUE would rise due to the alleviation of nutrient limitations. The response to N addition was negatively correlated with the ratio of fungi to bacteria, and presumably depended on the prevailing N-fertilisation regime. The temperature sensitivity of microbial metabolism was driven by site-specific parameters rather than by land-use type. Our results indicate that it may not be necessary to consider land use-specific temperature sensitivities when modelling soil organic carbon dynamics under future climate conditions.

Organisation(s)

Soil Science Section
Institute of Soil Science
Section Soil Chemistry

Type

Article

Journal

BIOGEOCHEMISTRY

Volume

160

Pages

105-125

No. of pages

21

ISSN

0168-2563

Publication date

08.2022

Publication status

Published

Peer reviewed

Yes

ASJC Scopus subject areas

Water Science and Technology, Earth-Surface Processes, Environmental Chemistry

Sustainable Development Goals

SDG 15 - Life on Land, SDG 13 - Climate Action

Electronic version(s)

https://doi.org/10.1007/s10533-022-00943-7 (Access: Open)