Prolonged suppression of ecosystem carbon dioxide uptake after an anomalously warm year

Arnone, John A.; Verburg, Paul; Johnson, Dale W.; Larsen, J. F.; Jasoni, Richard L.; Lucchesi, Annmarie J.; Batts, Candace M.; Nagy, Christopher von; Coulombe, W.; Schorran, David E.; Buck, Paul Η.; Braswell, B. H.; Coleman, James S.; Sherry, Rebecca A.; Wallace, Linda; Luo, Yiqi; Schimel, David

doi:10.1038/nature07296

Cited by 150 publications

(142 citation statements)

References 23 publications

Supporting

Mentioning

131

Contrasting

Unclassified

Order By: Relevance

“…Just as drought reducing productivity can be explained by reduced water availability limiting photosynthesis (23), heat waves can lower productivity by lowering soil moisture through increased evapotranspiration (12,24,25). Focusing on the indirect effects of heat waves on water balance allows for a common mechanism that links the effects of heat waves with drought and precipitation pattern, but other mechanisms are possible.…”

Section: Resultsmentioning

confidence: 99%

Timing of climate variability and grassland productivity

Craine

Nippert

Elmore

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

270

184

View full text Add to dashboard Cite

Future climates are forecast to include greater precipitation variability and more frequent heat waves, but the degree to which the timing of climate variability impacts ecosystems is uncertain. In a temperate, humid grassland, we examined the seasonal impacts of climate variability on 27 y of grass productivity. Drought and highintensity precipitation reduced grass productivity only during a 110-d period, whereas high temperatures reduced productivity only during 25 d in July. The effects of drought and heat waves declined over the season and had no detectable impact on grass productivity in August. If these patterns are general across ecosystems, predictions of ecosystem response to climate change will have to account not only for the magnitude of climate variability but also for its timing.Konza | net primary production | streamflow | critical climate periods F uture climates are likely to include more frequent droughts, high-intensity precipitation patterns, and heat waves, (i.e., periods of elevated air temperatures) (1, 2). At their most severe, extreme climate events, such as the mid-American heat waves of 1980 and 2011 and the 2003 European heat wave, involve months of hot, dry weather (3, 4), increasing mortality in humans and wildlife (5, 6) while reducing agricultural and natural-systems productivity (7-10). An increase in climate extremes would have unambiguously negative effects on ecosystems. However, most climate variability would not be considered extreme and occurs on much shorter time scales throughout the growing season with temperature and precipitation frequently disassociated. The response of ecosystems to short-term climate variability at different times of year is thought to vary (11-16), but we know little about how the timing of short-duration climate variability impacts key ecosystem dynamics such as plant productivity.To understand better how the timing of climate variability affects grassland productivity, we applied the critical climate period approach (17, 18) to long-term measurements of grass productivity in a humid, temperate grassland. Aboveground net primary productivity of grass (ANPP G ) was measured at the time of peak standing biomass from 1984-2010 in both shallow-soil upland and deep-soil lowland topographic positions in an annually burned, ungrazed watershed that is dominated by grasses with the C 4 photosynthetic pathway. In attempting to understand how the timing of climate variability affects grass productivity, we analyzed long-term records of precipitation, stream discharge, and air temperature to examine how variation in drought, precipitation intensity, and heat waves affect grass productivity at different times of the growing season. Results and DiscussionAcross 27 y, drought reduced grass productivity over a wide range of dates but had declining effects as the season progressed. ANPP G decreased with decreasing precipitation summed from April 15 to August 2 [day of year (DOY) 105-214] (Fig. 1). ANPP G declined 0.60 ± 0.12 g·m −2 for each millimeter decline in p...

show abstract

Section: Resultsmentioning

confidence: 99%

Timing of climate variability and grassland productivity

Craine

Nippert

Elmore

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

270

184

View full text Add to dashboard Cite

show abstract

“…In the long term, droughts might also influence vegetation composition. In general, impacts of droughts on the carbon cycle are difficult to assess, which is partly due to lagged effects like increased tree mortality in years after a severe drought (Bréda et al, 2006;Bigler et al, 2007), or changes in the respiration of soil heterotrophic organisms a year after an anomalously warm season (Arnone et al, 2008). Fires have an immediate and large impact on carbon stocks and vegetation structure (Westerling et al, 2006;Field et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Extreme events in gross primary production: a characterization across continents

et al. 2014

View full text Add to dashboard Cite

Abstract. Climate extremes can affect the functioning of terrestrial ecosystems, for instance via a reduction of the photosynthetic capacity or alterations of respiratory processes. Yet the dominant regional and seasonal effects of hydrometeorological extremes are still not well documented and in the focus of this paper. Specifically, we quantify and characterize the role of large spatiotemporal extreme events in gross primary production (GPP) as triggers of continental anomalies. We also investigate seasonal dynamics of extreme impacts on continental GPP anomalies. We find that the 50 largest positive extremes (i.e., statistically unusual increases in carbon uptake rates) and negative extremes (i.e., statistically unusual decreases in carbon uptake rates) on each continent can explain most of the continental variation in GPP, which is in line with previous results obtained at the global scale. We show that negative extremes are larger than positive ones and demonstrate that this asymmetry is particularly strong in South America and Europe. Our analysis indicates that the overall impacts and the spatial extents of GPP extremes are power-law distributed with exponents that vary little across continents. Moreover, we show that on all continents and for all data sets the spatial extents play a more important role for the overall impact of GPP extremes compared to the durations or maximal GPP. An analysis of possible causes across continents indicates that most negative extremes in GPP can be attributed clearly to water scarcity, whereas extreme temperatures play a secondary role. However, for Europe, South America and Oceania we also identify fire as an important driver. Our findings are consistent with remote sensing products. An independent validation against a literature survey on specific extreme events supports our results to a large extent.

show abstract

“…Tower flux measurements have shown a strong sensitivity of carbon exchange to surface temperature at several locations, including Niwot Ridge, Colorado (Sacks et al, 2007), Howland Forest, Maine (Richardson et al, 2007), and in the North American prairie region (Arnone et al, 2008). In this paper, we use measurements of column-averaged dry-air mole fractions of CO 2 , denoted X CO 2 , from the Total Carbon Column Observing Network (TCCON, Wunch et al, 2011a) and from the Greenhouse Gases Observing Satellite (GOSAT, Hamazaki, 2005;Yokota et al, 2009) to examine the interannual variability of the seasonal cycle minimum and its relationship with surface temperature.…”

Section: Introductionmentioning

confidence: 99%

The covariation of Northern Hemisphere summertime CO<sub>2</sub> with surface temperature in boreal regions

et al. 2013

View full text Add to dashboard Cite

Abstract. We observe significant interannual variability in the strength of the seasonal cycle drawdown in northern midlatitudes from measurements of CO 2 made by the Total Carbon Column Observing Network (TCCON) and the Greenhouse Gases Observing Satellite (GOSAT). This variability correlates with surface temperature in the boreal regions. Using TCCON measurements, we find that the slope of the relationship between the X CO 2 seasonal cycle minima and boreal surface temperature is 1.2 ± 0.7 ppm K −1 . Assimilations from CarbonTracker 2011 and CO 2 simulations using the Simple Biosphere exchange Model (SiB) transported by GEOS-Chem underestimate this covariation. Both atmospheric transport and biospheric activity contribute to the observed covariation.

show abstract

Prolonged suppression of ecosystem carbon dioxide uptake after an anomalously warm year

Cited by 150 publications

References 23 publications

Timing of climate variability and grassland productivity

Timing of climate variability and grassland productivity

Extreme events in gross primary production: a characterization across continents

The covariation of Northern Hemisphere summertime CO<sub>2</sub> with surface temperature in boreal regions

Contact Info

Product

Resources

About

Prolonged suppression of ecosystem carbon dioxide uptake after an anomalously warm year

Cited by 150 publications

References 23 publications

Timing of climate variability and grassland productivity

Timing of climate variability and grassland productivity

Extreme events in gross primary production: a characterization across continents

The covariation of Northern Hemisphere summertime CO&lt;sub&gt;2&lt;/sub&gt; with surface temperature in boreal regions

Contact Info

Product

Resources

About

The covariation of Northern Hemisphere summertime CO<sub>2</sub> with surface temperature in boreal regions