Your search keyword '"Vanhala, Pekka"' showing total 4 results

1. Transplantation of organic surface horizons of boreal soils into warmer regions alters microbiology but not the temperature sensitivity of decomposition.

Author

VANHALA, PEKKA, KARHU, KRISTIINA, TUOMI, MIKKO, BJÖRKLÖF, KATARINA, FRITZE, HANNU, HYVÄRINEN, HASSE, and LISKI, JARI

Subjects

*TAIGAS, *HUMUS, *VEGETATION & climate, *CLIMATE change, *GREENHOUSE effect, *CARBON cycle

Abstract

Changes in soil carbon, the largest terrestrial carbon pool, are critical for the global carbon cycle, atmospheric CO levels and climate. Climate warming is predicted to be most pronounced in the northern regions and therefore the large soil carbon pool residing in boreal forests will be subject to larger global warming impact than soil carbon pools in the temperate or the tropical forest. A major uncertainty in current estimates of the terrestrial carbon balance is related to decomposition of soil organic matter (SOM). We hypothesized that when soils are exposed to warmer climate the structure of the ground vegetation will change much more rapidly than the dominant tree species. This change will alter the quality and amount of litter input to the soil and induce changes in microbial communities, thus possibly altering the temperature sensitivity of SOM decomposition. We transferred organic surface soil sections from the northern borders of the boreal forest zone to corresponding forest sites in the southern borders of the boreal forest zone and studied the effects of warmer climate after an adaptation period of 2 years. The results showed that initially ground vegetation and soil microbial community structure and community functions were different in northern and southern forest sites and that 2 years of exposure to warmer climate was long enough to cause changes in these ecological indicators. The rate of SOM decomposition was approximately equally sensitive to temperature irrespective of changes in vegetation or microbial communities in the studied forest sites. However, as temperature sensitivity of the decomposition increases with decreasing temperature regime, the proportional increase in the decomposition rate in northern latitudes could lead to significant carbon losses from the soils. [ABSTRACT FROM AUTHOR]

Published

2011

2. Temperature sensitivity of soil carbon fractions in boreal forest soil.

Author

Karhu, Kristuna, Fritze, Hannu, Hämäläinen, Kai, Vanhala, Pekka, Jungner, Högne, Oinonen, Markku, Sonninen, Eloni, Tuomi, Mikko, Spetz, Peter, Kitunen, Veikko, and Liski, Jari

Subjects

TAIGAS, FOREST soils, FORESTS & forestry, GLOBAL warming, CARBON in soils, CLIMATE change, HISTOSOLS, BIOTIC communities, SOILS & climate

Abstract

Feedback to climate warming from the carbon balance of terrestrial ecosystems depends critically on the temperature sensitivity of soil organic carbon (SOC) decomposition. Still, the temperature sensitivity is not known for the majority of the SOC, which is tens or hundreds of years old. This old fraction is paradoxically concluded to be more, less, or equally sensitive compared to the younger fraction. Here, we present results that explain these inconsistencies. We show that the temperature sensitivity of decomposition increases remarkably from the youngest annually cycling fraction (Q10 < 2) to a decadally cycling one (Q10 = 4.2-6.9) but decreases again to a centennially cycling fraction (Q10 = 2.4-2.8) in boreal forest soil. Compared to the method used for current global estimates (temperature sensitivity of all SOC equal to that of the total heterotrophic soil respiration), the soils studied will lose 30-45% more carbon in response to climate warming during the next few decades, if there is no change in carbon input. Carbon input, derivative of plant productivity, would have to increase by 100-120%, as compared to the earlier estimated 70-80%, in order to compensate for the accelerated decomposition. [ABSTRACT FROM AUTHOR]

Published

2010

3. Temperature sensitivity of soil organic matter decomposition in southern and northern areas of the boreal forest zone

Author

Vanhala, Pekka, Karhu, Kristiina, Tuomi, Mikko, Björklöf, Katarina, Fritze, Hannu, and Liski, Jari

Subjects

*HUMUS, *CHEMICAL decomposition, *TEMPERATURE, *TAIGAS

Abstract

Abstract: Much effort has been made to improve understanding of factors controlling the temperature dependence of soil organic matter (SOM) decomposition. The question of how soils formed in different geographical locations and conditions respond to temperature changes is still open. In addition to climate, residence times of soil organic matter are controlled by its decomposability and microbial community. In this work we hypothesized that the decomposition of SOM is adapted to the prevailing SOM quality and climatic conditions. This should result in different temperature vs. decomposition curves for northern and southern soils. We studied short-term temperature dependence of SOM decomposition near the northern and southern borders of the boreal forest zone using a Gaussian model. As carbon mineralization rate is driven by microbial activity, we focused on organic carbon fractions available to microbes and the size, composition and functioning of microbial communities in the soil. Despite differences in microbial community structure and behavior, similar amounts and qualities of the microbially available carbon led to similar temperature dependences of carbon mineralization in the north and south. The overall soil respiration rate level was higher in spruce forest sites than in pine forest sites irrespective of climate conditions. Our results do not mean that there is no risk of carbon losses from northern soils due to warming climate conditions. As temperature sensitivity of the decomposition increases with decreasing temperature regime, the proportional increase in the decomposition rate in northern latitudes might lead to significant carbon losses from the soils. [Copyright &y& Elsevier]

Published

2008

4. Priming effect increases with depth in a boreal forest soil.

Author

Karhu, Kristiina, Hilasvuori, Emmi, Fritze, Hannu, Biasi, Christina, Nykänen, Hannu, Liski, Jari, Vanhala, Pekka, Heinonsalo, Jussi, and Pumpanen, Jukka

Subjects

*FOREST soils, *TAIGAS, *PHOTOSYNTHESIS, *HUMUS, *COMPOSTING

Abstract

Climate warming increases labile carbon (C) inputs to soil through increased photosynthesis and C allocation belowground. This could counterintuitively lead to losses of soil C via priming effects (PE): the stimulation of soil organic matter (SOM) decomposition caused by labile C addition. Systematic quantification of PEs in different ecosystems is needed. We measured PEs of free-living soil microbes in different layers of a boreal forest soil, and found that the relative magnitude of the PE increased with soil depth. The relationship between relative PE and the added glucose amount also depended on the soil layer. Our results indicate that the decomposition of SOM in deeper soil layers could be significantly increased due to PE, if labile C inputs into these layers increase. [ABSTRACT FROM AUTHOR]

Published

2016