Northern hemisphere photosynthetic trends 1982–99

Slayback, D. A.; Pinzón, Jorge Enrique Dí­az; Los, S.O.; Tucker, Compton J.

doi:10.1046/j.1365-2486.2003.00507.x

Cited by 390 publications

(289 citation statements)

References 27 publications

(35 reference statements)

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“…Most areas show an increase in NDVI for this period; the exceptions are the Sahara which shows no change and areas in the western parts of North America, south of the Amazon (South America), in central Asia, and central Australia, which show a decrease. Positive trends in similar NDVI data were reported in other studies as well [Myneni et al, 1997;Tucker et al, 2001;Slayback et al, 2003;Nemani et al, 2003]; the large negative excursion in NDVI during the early part of the time series, 1985-1986, makes a very important contribution to these trends. Compared to the control, both positive and negative trends in the fused AVHRR MODIS NDVI + CO 2 data (supporting information) are larger; the largest increases are found in western and central Europe and the highlands in eastern Africa.…”

Section: Trends In Annual Datasupporting

confidence: 87%

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO₂ fertilization effect in global vegetation

Los

2013

Global Biogeochemical Cycles

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[1] Recent studies report an increase in vegetation greenness in mid-to-high northern latitudes. This increase is observed in leaf-out data in Europe and North America since the 1950s and in satellite data since the 1980s. Increased vegetation greenness is potentially a factor contributing to a land CO 2 sink. Various causes for increased vegetation greenness are suggested, but their relative importance is uncertain. In the present study, the effect of climate and CO 2 fertilization on increased vegetation greenness and the land CO 2 sink are investigated. The study is organized as follows: (1) (2) Residuals between RVI and NDVI are analyzed for associations with variations in downwelling solar radiation, nitrogen deposition, satellite-related artifacts, and CO 2 fertilization. CO 2 fertilization was the only factor that improved RVI modeling. (3) The effect of climate variations and CO 2 fertilization on the land CO 2 sink, as manifested in the RVI, is explored with the Carnegie Ames Stanford Assimilation (CASA) model. Climate (temperature and precipitation) and CO 2 fertilization each explain approximately 40% of the observed global trend in NDVI for 1982-2006 . For 1901-2006, estimated trends in NDVI related to CO 2 fertilization are four to five times larger than climate-related trends. CASA simulations indicate that the CO 2 fertilization effect on vegetation greenness contributes about 0.7 Pg C per year to the recent land CO 2 sink. This is a conservative estimate and is likely larger. This effect of CO 2 fertilization would be a large component of the land carbon sink. In the supporting information the RVI is used as a common standard to fuse MODIS and advanced very high resolution radiometer (AVHRR) NDVI data. This fusion compares well with SeaWiFS data.

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Section: Trends In Annual Datasupporting

confidence: 87%

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO₂ fertilization effect in global vegetation

Los

2013

Global Biogeochemical Cycles

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“…Even when NEP is enhanced, changes in disturbance regimes will affect NBP. Myneni et al (2001) observed C losses over much of Canada's boreal forests during the 1980s and 1990s despite the fact that increased photosynthetic activity had been observed during this same time period (Myneni et al 1997;Slayback et al 2003). These losses were brought about by increased disturbances (Kurz & Apps 1999).…”

Section: Discussionmentioning

confidence: 99%

“…Chief among these are: (i) elevated atmospheric CO 2 concentrations, (ii) increased atmospheric N deposition, and (iii) longer growing seasons. The combined effect of these processes on the longerterm net C balance remains a topic of scientific discussion (Angert et al 2005;de Vries et al 2006;Euskirchen et al 2006), but remote sensing data suggest that these factors could be driving substantial increases in photosynthetic activity (Myneni et al 1997;Slayback et al 2003). Estimates suggest that net primary production (NPP) has increased by 6% globally during the 1980s and 1990s (Nemani et al 2003), and atmospheric inversion studies suggest that C storage in the boreal forest has been increasing since the early 1980s (Dargaville et al 2006).…”

Section: Introductionmentioning

confidence: 99%

Could increased boreal forest ecosystem productivity offset carbon losses from increased disturbances?

Kurz

Stinson

Rampley

2007

Phil. Trans. R. Soc. B

103

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To understand how boreal forest carbon (C) dynamics might respond to anticipated climatic changes, we must consider two important processes. First, projected climatic changes are expected to increase the frequency of fire and other natural disturbances that would change the forest age-class structure and reduce forest C stocks at the landscape level. Second, global change may result in increased net primary production (NPP). Could higher NPP offset anticipated C losses resulting from increased disturbances? We used the Carbon Budget Model of the Canadian Forest Sector to simulate rate changes in disturbance, growth and decomposition on a hypothetical boreal forest landscape and to explore the impacts of these changes on landscape-level forest C budgets. We found that significant increases in net ecosystem production (NEP) would be required to balance C losses from increased natural disturbance rates. Moreover, increases in NEP would have to be sustained over several decades and be widespread across the landscape. Increased NEP can only be realized when NPP is enhanced relative to heterotrophic respiration. This study indicates that boreal forest C stocks may decline as a result of climate change because it would be difficult for enhanced growth to offset C losses resulting from anticipated increases in disturbances.

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“…The GIMMS NDVI products, with a spatial resolution of 8 km, were compiled by merging segments (data strips) of a half-month period using the MVC method (Holben, 1986). These data had been calibrated for sensor shifts, and corrected to remove the effects of sensor degradation, satellite orbit drift, solar zenith angles and other factors, such as the effects of stratospheric aerosol loadings from the El Chichon and Mount Pinatubo eruptions in April 1984 and June 1991 (Zhou et al, 2001;Slayback et al, 2003).…”

Section: Ndvi Dataset From Gimmsmentioning

confidence: 99%

Start of vegetation growing season on the Tibetan Plateau inferred from multiple methods based on GIMMS and SPOT NDVI data

Ding

Zhang

et al. 2015

J. Geogr. Sci.

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Abstract:In this study, we have used four methods to investigate the start of the growing season (SGS) on the Tibetan Plateau (TP) from 1982 to 2012, using Normalized Difference Vegetation Index (NDVI) data obtained from Global Inventory Modeling and Mapping Studies (GIMSS, 1982(GIMSS, -2006 and SPOT VEGETATION (SPOT-VGT, 1999. SGS values estimated using the four methods show similar spatial patterns along latitudinal or altitudinal gradients, but with significant variations in the SGS dates. The largest discrepancies are mainly found in the regions with the highest or the lowest vegetation coverage. Between 1982 and 1998, the SGS values derived from the four methods all display an advancing trend, however, according to the more recent SPOT VGT data (1999, there is no continuously advancing trend of SGS on the TP. Analysis of the correlation between the SGS values derived from GIMMS and SPOT between 1999 and 2006 demonstrates consistency in the tendency with regard both to the data sources and to the four analysis methods used. Compared with other methods, the greatest consistency between the in situ data and the SGS values retrieved is obtained with Method 3 (Threshold of NDVI ratio). To avoid error, in a vast region with diverse vegetation types and physical environments, it is critical to know the seasonal change characteristics of the different vegetation types, particularly in areas with sparse grassland or evergreen forest.

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Northern hemisphere photosynthetic trends 1982–99

Cited by 390 publications

References 27 publications

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO₂ fertilization effect in global vegetation

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO₂ fertilization effect in global vegetation

Could increased boreal forest ecosystem productivity offset carbon losses from increased disturbances?

Start of vegetation growing season on the Tibetan Plateau inferred from multiple methods based on GIMMS and SPOT NDVI data

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Northern hemisphere photosynthetic trends 1982–99

Cited by 390 publications

References 27 publications

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO2 fertilization effect in global vegetation

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO2 fertilization effect in global vegetation

Could increased boreal forest ecosystem productivity offset carbon losses from increased disturbances?

Start of vegetation growing season on the Tibetan Plateau inferred from multiple methods based on GIMMS and SPOT NDVI data

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Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO₂ fertilization effect in global vegetation

Analysis of trends in fused AVHRR and MODIS NDVI data for 1982–2006: Indication for a CO₂ fertilization effect in global vegetation