Long-Term Effects of Climate Warming on Forest Soil Collembola

Abstract The biogenic volatile organic compounds, BVOCs have a central role in ecosystem–atmosphere interactions. High-latitude ecosystems are facing increasing temperatures and insect herbivore pressure, which may affect their BVOC emission rates, but evidence and predictions of changes remain scattered. We studied the long-term effects of + 3 °C warming and reduced insect herbivory (achieved through insecticide sprayings) on mid- and late summer BVOC emissions from field layer vegetation, supplemented with birch saplings, and the underlying soil in Subarctic mountain birch forest in Finland in 2017–2018. Reduced insect herbivory decreased leaf damage by 58–67% and total ecosystem BVOC emissions by 44–72%. Of the BVOC groups, total sesquiterpenes had 70–80% lower emissions with reduced herbivory, and in 2017 the decrease was greater in warmed plots (89% decrease) than in ambient plots (34% decrease). While non-standardized total BVOC, monoterpene, sesquiterpene and GLV emissions showed instant positive responses to increasing chamber air temperature in midsummer samplings, the long-term warming treatment effects on standardized emissions mainly appeared as changes in the compound structure of BVOC blends and varied with compounds and sampling times. Our results suggest that the effects of climate warming on the total quantity of BVOC emissions will in Subarctic ecosystems be, over and above the instant temperature effects, mediated through changes in insect herbivore pressure rather than plant growth. If insect herbivore numbers will increase as predicted under climate warming, our results forecast herbivory-induced increases in the quantity of Subarctic BVOC emissions. Graphic Abstract

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Temperature Influence on Pseudothecia Development Stages of Venturia inaequalis in the Western Cape of South Africa

Plant Disease ◽

10.1094/pdis-04-19-0706-re ◽

2020 ◽

Vol 104 (1) ◽

pp. 147-153

Author(s):

S. G. von Diest ◽

J. C. Meitz-Hopkins ◽

A. A. Rabie ◽

W. E. MacHardy ◽

C. L. Lennox

Keyword(s):

South Africa ◽

Climate Warming ◽

Venturia Inaequalis ◽

Apple Scab ◽

Western Cape ◽

Cold Winter ◽

Long Term Effects ◽

Region Of Origin ◽

Development Stages

Pseudothecia development stages of Venturia inaequalis (apple scab) were investigated in two climatically different regions in the Western Cape of South Africa. The aim was to determine the pseudothecial density (PD; pseudothecia per fertile lesion [p/f]) and ascal density (AD; asci per pseudothecium [a/p]) that contributes to defining the potential ascospore dose in a common prediction model of the apple scab infection risk. The PD and AD were compared between Elgin (EL), now considered a warm winter apple-growing region because of climate warming, and Koue Bokkeveld (KB), a cold winter region. In 2012 and 2013, scabbed apple leaves were collected during leaf-drop in KB and EL and overwintered either in their region of origin or in the other region. PD was significantly higher in scabbed leaves collected and overwintered in KB (mean, 24.11 p/f) than in leaves collected in KB and overwintered in EL (mean, 17.11 p/f; P < 0.001). PD of scabbed leaves collected and overwintered in EL (mean, 15.27 p/f) or collected in EL and overwintered in KB (mean, 16.07 p/f) did not differ significantly. Ascal density did not differ significantly in any treatment or season. We concluded that the significantly higher PD of scabbed leaves collected from the cooler region of KB and overwintered in KB compared with scabbed leaves collected in EL or KB and overwintered in EL could be caused by adaptations of V. inaequalis populations to the respective climates. This implied long-term effects of climate warming on apple scab epidemiology and management.

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Long-term effects of stump removal to control root rot on forest soil bulk density, soil carbon and nitrogen content

Forest Ecology and Management ◽

10.1016/j.foreco.2007.09.046 ◽

2008 ◽

Vol 255 (3-4) ◽

pp. 720-727 ◽

Cited By ~ 36

Author(s):

D. Zabowski ◽

D. Chambreau ◽

N. Rotramel ◽

W.G. Thies

Keyword(s):

Nitrogen Content ◽

Bulk Density ◽

Forest Soil ◽

Root Rot ◽

Soil Bulk Density ◽

Long Term Effects ◽

Carbon And Nitrogen ◽

Control Root ◽

Carbon And Nitrogen Content

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Mediating the Effects of Climate on the Temperature and Thermal Structure of a Monomictic Reservoir through Use of Hydraulic Facilities

Water ◽

10.3390/w13081128 ◽

2021 ◽

Vol 13 (8) ◽

pp. 1128

Author(s):

Maurice Alfonso Duka ◽

Tetsuya Shintani ◽

Katsuhide Yokoyama

Keyword(s):

Climate Change ◽

Surface Water ◽

Climate Warming ◽

Thermal Structure ◽

Heat Content ◽

Thermal Conditions ◽

Long Term Effects ◽

Air Temperatures ◽

Lower Heat

Climate warming can alter the thermal conditions of reservoirs. However, some hydraulic interventions can be explored to mitigate this impact. This study investigates the long-term effects of climate on the temperature and thermal structure of a monomictic reservoir that has had varying operations from 1959 to 2016. Reservoir progressively operated through three distinct periods, namely, (A) deep penstock withdrawal (DPW; 1959–1991), (B) purely selective withdrawal (SW; 1992–2001), and (C) combination of SW and vertical curtain (VC; 2002–2016). Although annual air temperatures are increasing (+0.15 °C decade−1) in the long term, the reservoir’s surface water temperatures have been found to be decreasing (−0.06 °C decade−1). Periods B and C produced colder profiles and exhibited lower heat content and higher potential energy anomaly than Period A. Furthermore, stronger thermoclines, as indicated by Brunt–Vaisala frequency, were observed in the two latter periods. The results of this study show that varying operations bear a stronger influence on the reservoir’s temperature and thermal structure than climate change itself. Mitigating the thermal impacts of climate warming in reservoirs appears promising with the use of SW and VC.

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