Abstract
The El Niño-Southern Oscillation (ENSO) is the main driver of interannual climate extremes in Amazonia and other tropical regions. The current 2015/2016 EN event was expected to be as strong as the EN of the century in 1997/98, with extreme heat and drought over most of Amazonian rainforests. Here we show that this protracted EN event, combined with the regional warming trend, was associated with unprecedented warming and a larger extent of extreme drought in Amazonia compared to the earlier strong EN events in 1982/83 and 1997/98. Typical EN-like drought conditions were observed only in eastern Amazonia, whilst in western Amazonia there was an unusual wetting. We attribute this wet-dry dipole to the location of the maximum sea surface warming on the Central equatorial Pacific. The impacts of this climate extreme on the rainforest ecosystems remain to be documented and are likely to be different to previous strong EN events.
The Amazon basin has warmed by 0.5 °C since 1980, with stronger warming during the dry season and over the southeast1,2. Together with warming, the last decade has experienced two major droughts in a very short period3,4,5,6, raising concerns about the resilience of tropical forests to extreme droughts and impacts of global warming over this biome. Extreme climatic events over Amazonia are mainly linked to El Niño-Southern Oscillation (ENSO) conditions in the tropical Pacific, but also to sea surface temperature (SST) anomalies in the tropical Atlantic, or to a combination of both7. The occurrence of these extreme events severely disrupts the livelihood of riverine populations7 as well as the water and carbon cycling of the extensive tropical forests2,8,9,10,11.
Warm EN events are associated to periodic droughts in Amazonia because of a suppression of the convection and thus rainfall in northern, eastern and western Amazonia5,7,12. Because of the different pattern observed in the tropical Pacific SST anomalies during El Niño events, two types of El Niño have been recently suggested depending on whether the maximum warming is located in the Eastern Pacific (EP) or the Central Pacific (CP). The impacts of these two types of El Niño on the Amazon climate and ecosystems can be markedly different because of the particular convection patterns and atmospheric response linked to EP and CP warmings13. These two EN flavours do not imply a dichotomy, as events can be found in-between14. In fact, the EN of 1982/83 and 1997/98 can be considered to belong to a separate strong EN regime, with particularly large warming in the EP, as opposed to a moderate regime as occurs for the other observed EN, thus leading to a reinterpretation of the canonical and Modoki El Niño commonly associated to EP and CP anomalies, respectively15,16.
In particular, the 1997/98 event was considered as the climate event of the twentieth century for its extraordinary magnitude with consequences at global scale17. In 2014, anomalous warm SSTs in the central Pacific together with anomalous westerly wind patterns led to some agencies and ENSO experts to alert about the possibility of the first extreme EN event since 199717. Although the EN-2014 conditions were finally not strong enough for this to happen, its warming remnants in the central Pacific may have contributed to start the strong EN-201518. This is the first strong EN in the last 18 years, and it could be expected to result in strong warming and drought over Amazonia, amplified by the ongoing warming trend. Here we use reanalysis and observation-based climate datasets to quantify the warming and drought severity during 2015/2016 over the Amazon forest in the context of the two previous strong EN events (1982/83 and 1997/98).
Results
Climate data
We use monthly sea/land surface temperatures and the self-calibrating Palmer Drought Severity Index (scPDSI)19 computed using meteorological fields from the ERA-Interim (ERA-I) reanalysis between January 1979 and March 2016. ERA-I provides up-to-date physically consistent meteorological fields and has been shown to perform better than other modern reanalyses in Amazonia20. Sea surface temperature anomalies were analyzed over the Pacific and Atlantic regions EN12, EN34, TNA and TSA (Supplementary Fig. S1). Additionally, we used the E and C indices to assess the contribution of the EP and CP types of El Niño15.
Land surface temperature (LST) anomalies and scPDSI were analyzed over the Amazon forest area defined as Evergreen Broadleaf Forest class in MODIS 0.05° resolution MCD12C1 land cover product (Supplementary Fig. S1). Details on the climate and remote sensing datasets, as well as processing methods, are provided in the Methods section. Additional results and intercomparison between products are also included in the Supplementary Material.
Evolution of surface temperature anomalies
SST anomalies over EN34 region show a peak >2.5 °C in November 2015, representing the highest anomaly since 1979, comparable and perhaps slightly higher than the 1997 and 1982 values (Supplementary Fig. S2), although the global warming trend and differences among datasets complicates ranking these events. The temporal evolution of SST anomalies during the developing EN year (January to December) in 1982, 1997 and 2015 are similar, with an increasing trend from January to the peak in November in 1997 and 2015, and the peak in December in 1982, with 2015 typically showing the strongest warming. SST warm anomalies show a decrease to neutral conditions from January 1983, 1998 and 2016 for the three EN events, respectively. SST anomalies over other sensitive regions (e.g. EN12 and the TNA-TSA gradient) are markedly different during the three events (Supplementary Fig. S2), which may explain the different local and regional effects of rainfall patterns over land.
Land surface temperature anomalies over Amazonia broke a record in 2015 (Fig. 1a). Warming peaked in October 2015, and was stronger by 1.5 °C than the peak observed in October 1997, and 2 °C stronger than the peak observed in January 1983. In fact, the warming over Amazonia is hardly observable during the OND season in 1982. The warming was more clear during the OND season in 1997, but the OND season in 2015 shows the widest and strongest warming (Fig. 1b). Warming remnants are also observed in JFM-1998 and JFM-2016, and a cooling transition in JFM-1983.
However, one of the most significant differences between the three events is observed for the pre-EN years, namely, 1981, 1996 and 2014. Warming over Amazonia is also evident in 2014, with a peak in September 2014 (anomaly higher than 1 °C), whereas cooling or neutral conditions are observed in 1981 and 1996 (Fig. 1a). The warm conditions in 2014 (in both the Amazon basin and the adjacent sea regions) that may helped to the ignition of the EN-2015, which were not observed in 1982 and 1981 and 1996, are clearly evidenced in the spatial distribution of thermal anomalies (Suplementary Figs S3–S5).
The different faces of El Niño: EP and CP contributions
The contrasting temperature anomalies can be attributed to some extent to the different contribution of the EP and CP SST anomalies among the three EN events. Analysis of E and C indices shows that EN events in 1982 and 1997 are characterized by a strong contribution of the E index (> +3) (Supplementary Fig. S6a). The contribution of the E index to EN-2015 is also strong (about +2), but considerably below the values obtained for EN-1982 and EN-1997. However, EN-2015 is characterized by a strong contribution of the C index (> +2), with a similar C index than the value reached in EN-2009 (Supplementary Fig. S6b). The C contribution was low for EN-1982 and EN-1997. Both E and C contributions peaked in December 2015, with a strong decay from January to June 2016.
Analysis of spatial patterns shows that the reduced EN signal in JAS 1982 can be explained in part by the delayed eastern Pacific warming (Supplementary Figs S7a,c–S8a). On the other hand, the EN contribution to the OND warming was similar in all three events (Supplementary Fig. S8b,d,f) but the warming trend had an important effect both in JAS and OND (Supplementary Fig. S9), making 2015 the warmest and 1982 the coolest of the three events.
Drought severity
2015 saw record-breaking warming in Amazonia. However, did this anomalous warming translate into enhanced drought conditions? The scPDSI suggests that up to a third of the Amazon rainforest is typically affected by moderate (scPDSI < –2) to severe (scPDSI < –3) drought conditions during strong EN years (Fig. 2). The extremely hot 2015/2016 event stands out by having the most extensive area under extreme drought severity (scPDSI < –4), with up to 13% of the rainforests undergoing extreme drought in February-March 2016 (Fig. 2a). This is up to a fifth more extreme drought area than in previous events, where such an intense drought severity did not affect more than 8-10% of the rainforests.
The spatial distribution of drought in 2015/2016 departed from the typical pattern seen in previous major EN events when drought was less severe but more widespread over Amazonia (Fig. 2b). This time, there was an unusual wet-dry dipole between southwestern and northeastern Amazonia. As a result, the mostly extreme drought conditions concentrated into a smaller region in the northeast. The moisture contrast is not a model artefact as it is also evident in precipitation anomalies of independent precipitation datasets based on satellite and in-situ observations (Supplementary Fig. S10). A similar wet-dry dipole was observed during EN 2009/2010 (Supplementary Fig. S11). Because of the strong contribution of the C index in EN 2009 and 2015, this wet/dry contrast can be attributed in large part to the different precipitation patterns resulting from El Niño warming in the central Pacific (2009 and 2015) and the eastern Pacific (1982 and 1997).
Discussion
The year 2015 surpassed any warming anomaly observed in the last decade that has seen ‘one in a century’ extreme events (e.g., droughts of 2005 and 2010). Analysis of long-term temperature records suggests that 2015 is likely the hottest year over Amazonia in the last century (Supplementary Fig. S12) due to the combined effects of the El Niño conditions and the regional warming trend. The extreme heat coincided with an increased extent of extreme drought severity (scPDSI < −4) – a drought magnitude that occurs only in 2% of the months since January 1979.
Warming can further enhance drought severity from precipitation deficit through an increase in potential evapotranspiration (PET)19. As expected, PET was anomalously high during the period with record warming in late 2015 (Supplementary Fig. S15). To quantify the impact of warming on drought severity we compared the drought areas resulting from the scPDSI computed using varying PET (includes effect of warming) and PET set to climatological values (no effect of warming). This suggests that warming accounts for about a fifth of the anomalously high area under extreme drought severity observed during 2015/2016 (Supplementary Fig. S15). By March 2016, the effect of temperature on drought severity led to an additional 2.6% of the rainforests under extreme drought severity. For less intense drought severities, the effect of warming was almost negligible. This is consistent with the fact that the regions affected by extreme drought in eastern Amazonia coincided with those experiencing record warming (Figs 1b and 2b). Further work that considers the surface energy budget and land surface feedbacks21 would help to better quantify the impact of the record-breaking warming on drought across the basin.
Currently, ENSO neutral conditions are present, indicating that the warming phase is over. Different forecasts predict a transition to La Niña conditions during the boreal fall and winter 2016–2017 with varying probabilities (75% to 60%)22,23, although current conditions for equatorial heat discharge and easterly winds may suggest a lower probability for La Niña to occur (∼50%). Like in the 1982/83 and 1997/98 EN events (Supplementary Fig. S13), the seasons following El Niño peak in 2016 may also experience a significant warming over Amazonia. Although LST products derived from remote sensing data should be interpreted with caution over cloudy tropical regions24, satellite-based temperature anomalies over Amazonia still show a widespread warming in AMJ-2016. Moreover, drought conditions were still developing by the end of our study period in March 2016, but should have peaked by May or June.
The impacts of the observed climate anomalies on ecosystem function are still uncertain and remain to be documented. A number of studies reported impacts of earlier extreme temperature and drought events on rainforest. Tree mortality and biomass growth decline were observed after the 2005 and 2010 droughts, with implications also for the persistence of the Amazon forest as a carbon sink8,9,10. These impacts may be attributed not only to water deficits8 but also to heat stress9, with anomalously high air temperatures playing a role as important as precipitation deficits25,26. Fires in forested areas have been suggested to be the major agent of forest transition under an increased drought frequency scenario27. It is also believed that hot and dry conditions during EN years turn the Amazon ecosystem into a net carbon source28. However, it is has also been suggested that this only occurs during El Niño events with prevailing EP anomalies, whereas the Amazon rainforest remains a carbon sink during El Niño events with major contributions from CP anomalies13. Under continued global warming and a projected increase in the frequency of ENSO events29 more frequent record-breaking climate extremes are expected to occur in Amazonia during the coming decades.
Methods
Study regions
The Amazon forest was delimited by using the Combined Terra/Aqua yearly Land Cover product (MCD12C1)30. For this purpose, we selected pixels classified as “Evergreen Broadleaf Forest – EBF” within an area delimited by a geographical vector constructed from the political borders including South American provinces around the Amazonian forests. SST anomalies were extracted for the following sea regions: regions for El Niño 1 + 2 (EN12; 90°W–80°W, 0°–10°S), El Niño 3.4 (EN34; 120°W–170°W, 5°S–5°N), Tropical North Atlantic (TNA; 15°W–57.5°W; 5.5°N–23.5°N), and Tropical South Atlantic (TSA; 10°E–30°W, 0°–20°S). The analysis for the TNA and TSA regions was performed in terms of the gradient between the two regions (TNA-TSA). These study regions were also considered in other works1. The study regions are presented in Supplementary Fig. S1. Additionally, we used the E and C indices15 that correspond to SST anomaly patterns representing eastern and central equatorial Pacific warming, respectively (updated in near-real time at http://www.met.igp.gob.pe/datos/EC.txt).
Skin and surface air temperatures
We used in our analysis monthly means of skin temperature (including both sea and land surface temperatures) extracted from the ERA-Interim (ERA-I) project developed by the European Centre for Medium-Range Weather Forecasts (ECMWF) at 0.75° × 0.75° latitude longitude global spatial resolution31. ERA-I covers the period from January 1979 until present, with a delay on the data delivery of around 2 months.
In order to extend back the study period to 1900, we used ERA20C and HadCRUT4 datasets of monthly temperature. ERA20C is the first reanalysis of the 20th-century developed by the ECMWF at 1° × 1° latitude longitude global spatial resolution covering the period 1900–201032. ERA20C monthly temperatures were calibrated against the ERA-I temperatures for the overlapping period (1979–2010), and ERA20C was combined to ERA-I to obtain the monthly anomalies of skin temperature from 1900 to 2015 (Supplementary Fig. S7a). HadCRUT4 dataset includes monthly surface temperature anomalies relative to a 1961–1990 reference period on a 5° grid. This dataset is a collaborative product of the Met Office Hadley Centre and the Climatic Research Unit (CRU) at the University of East Anglia33. Note that ERA20C/ERA-I provides skin temperature, whereas HadCRUT4 provides air temperature.
Surface temperature anomalies at higher spatial resolution than the reanalysis and climate datasets were extracted from the Moderate resolution Imaging Spectrometer (MODIS) products at 0.05° spatial resolution (Supplementary Fig. S14). MODIS data over the Amazon region was extracted from the Thermal Amazoni@ web-based interface34.
Monthly temperatures extracted from the different datasets were converted to temperature anomalies and also to standardized anomalies. In the case of the ERA-I dataset, the reference climatological period was 1980–2014. ERA20C anomalies were obtained from a reference period of 1961–1990 in order to be consistent with the reference period used in the HadCRUT4 dataset (temperature anomalies are directly provided in this dataset, so additional calculations are not required). Surface temperature anomalies derived from remote sensing data (MODIS) were calculated using a reference period of 2001–2014.
Standardized anomalies were computed from the ratio between anomalies and the standard deviation for the reference period. Maps of standardized anomalies (e.g. Supplementary Figs S10b and S14) were categorized into 3 levels of significance: values between 0 and 1 are considered not significant, values between 1 and 1.96 are related to a probability of being anomalous between 1 and 2 sigma (68% to 95%), and values higher than 1.96 indicate a probability of being anomalous higher than 2-sigma (>95%).
Self-calibrating Palmer Drought Severity Index
Monthly surface moisture variability over the period 1979–2016 was characterised using the Self-calibrating Palmer Drought Severity Index (scPDSI)35, which is a relative drought index that describes the severity of droughts and pluvials by comparison with the variations experienced during a reference period. The standardized moisture anomalies are derived from a basic soil moisture budget for the rooting zone that accounts for local soil water holding capacity, precipitation (moisture supply) and actual and potential evapotranspiration (moisture demand). The resulting index correlates well with variations in soil moisture, terrestrial water storage and runoff19,36. We computed the scPDSI for the Amazon basin at a spatial resolution of 0.5° using monthly precipitation and potential evapotranspiration (PET) from ERA-I reanalysis, and soil water holding capacity data from the Food and Agriculture Organization digital soil map of the world37. The calibration of the index was done over the reference period 1979–2015.
Monthly precipitation was derived from monthly means of daily forecast accumulations (MDFA) data. The MDFA are produced by averaging twice daily forecasts (00 and 12 UTC) over the month for forecast ranges of 0–12 hours, 12–24 hours and 24–36 hours31. For this work, drought severity was computed independently using the three different forecast ranges and then an ensemble average was produced. Monthly PET was computed using the Penman-Monteith method34 from monthly fields of surface net radiation, specific humidity, air temperature, wind velocity, and surface pressure data.
Precipitation
Three precipitation datasets based on station and/or satellite records were used to evaluate the reliability of ERA-I precipitation estimates (Supplementary Fig. S10). This includes the 3B43 (V7) product from the Tropical Rainfall Measuring Mission (TRMM) Multisatellite Precipitation Analysis (TMPA)38, Global Precipitation Climatology Project (GPCP) dataset39, and the station-based Global Surface Summary of the Day (GSOD) product from the National Climate Data Center. Products were intercompared for the period 1998–2015 (Supplementary Fig. S10a).
Additional Information
How to cite this article: Jiménez-Muñoz, J. C. et al. Record-breaking warming and extreme drought in the Amazon rainforest during the course of El Niño 2015–2016. Sci. Rep. 6, 33130; doi: 10.1038/srep33130 (2016).
Supplementary Material
Acknowledgments
This work was supported in part by the Ministerio de Ciencia e Innovación (CEOS-Spain2, ESP2014-52955-R) and CONICYT (Fondecyt-Initial, Ref. 11130359). J. B. was partially supported by the grant CONICYT/FONDAP/1511000.
Footnotes
Author Contributions J.C.J.-M., C.M. and J.B. conceived the study, wrote the paper and carried out the data analysis. A.S.-A. contributed to the processing and information extraction from the reanalysis datasets. K.T. contributed to the analysis of EN events and C/E indices. Y.M., J.A.S. and G.v.d.S. reviewed the paper and contributed to overall scientific discussion.
References
- Jiménez-Muñoz J. C., Sobrino J. A., Mattar C. & Malhi Y. Spatial and temporal patterns of the recent warming of the Amazon forest. J. Geophys. Res. 118, 5204–5215 (2013). [Google Scholar]
- Gloor M. et al. Recent Amazon climate as background for possible ongoing and future changes of Amazon humid forests. Glob. Biogeochem. Cycles 29, 1384–1399 (2015). [Google Scholar]
- Marengo J. A. et al. The Drought of Amazonia in 2005. J. Clim. 21(3), 495–516 (2008). [Google Scholar]
- Marengo J. A., Tomasella J., Alves L. M., Soares W. & Rodriguez D. A. The drought of 2010 in the context of historical droughts in the Amazon region. Geophys. Res. Lett. 38, 1–5 (2011). [Google Scholar]
- Espinoza J. C. et al. Climate variability and extremes drought in the upper Solimões River (Western Amazon Basin): Understanding the exceptional 2010 drought. Geophys. Res. Lett. 38, L13406 (2011). [Google Scholar]
- Lewis S. L., Brando P. M., Phillips O. L., vand der Heijden G. F. M. & Nepstad D. The 2010 Amazon drought. Science 331, 554 (2011). [DOI] [PubMed] [Google Scholar]
- Marengo J. A. & Espinoza J. C. Extreme seasonal droughts and floods in Amazonia: causes, trends and impacts. Int. J. Climatol. 36, 1033–1050 (2016). [Google Scholar]
- Phillips O. L. et al. Drought sensitivity of the Amazon rainforest. Science 323, 1344–1347 (2009). [DOI] [PubMed] [Google Scholar]
- Toomey M., Roberts D. A., Still C., Goulden M. L. & McFadden J. P. Remotely sensed heat anomalies linked with Amazonian forest biomass declines. Geophys. Res. Lett. 38, L19704 (2011). [Google Scholar]
- Gatti L. V. et al. Drought sensitivity of Amazonian carbon balance revealed by atmospheric measurements. Nature 506, 76–80 (2014). [DOI] [PubMed] [Google Scholar]
- Maeda E. E., Kim H., Aragão L. E. O. C., Famiglietti J. S. & Oki T. Disruption of hydroecological equilibrium in southwest Amazon mediated by Drought. Geophys. Res. Lett. 42, 7546–7553 (2015). [Google Scholar]
- Malhi Y. et al. Climate Change, Deforestation, and the Fate of Amazon. Science 319, 169–172 (2008). [DOI] [PubMed] [Google Scholar]
- Li W., Zhang P., Ye J., Li L. & Baker P. A. Impact of two different types of El Niño events on the Amazon climate and ecosystem productivity. J. Plant Ecol. 4(1–2), 91–99 (2011). [Google Scholar]
- Capotondi A. et al. Understanding ENSO diversity. Bull. Amer. Meteor. Soc. 96(6), 921–938 (2014). [Google Scholar]
- Takahashi K., Montecinos A., Goubanova K. & Dewitte B. ENSO regimes: Reinterpreting the canonical and Modoki El Niño. Geophys. Res. Lett. 38, L10704 (2011). [Google Scholar]
- Takahashi K. & Dewitte B. Strong and moderate nonlinear El Niño regimes. Clim. Dyn. 46, 1627–1645 (2016). [Google Scholar]
- Santoso A. et al. ENSO extremes and diversity. Dynamics, Teleconnections, and Impacts. Bull. Amer. Meteor. Soc. 1969–1972 (2015). [Google Scholar]
- McPhaden M. J. Playing hide and seek with El Niño. Nat. Clim. Chang. 5(9), 791–795 (2015). [Google Scholar]
- van der Schrier G., Barichivich J., Briffa K. R. & Jones P. D. A scPDSI-based global data set of dry and wet spells for 1901–2009. J. Geophys. Res. Atmos. 118, doi: 10.1002/jgrd.50355 (2013). [DOI] [Google Scholar]
- Lorenz C. & Kunstmann H. The Hydrological Cycle in Three State-of-the-Art Reanalyses: Intercomparison and Performance Analysis. J. Hydrometeor. 13, 1397–1420 (2012). [Google Scholar]
- Seneviratne S. I. et al. Changes in climate extremes and their impacts on the natural physical environment (eds Field C. B. et al.) Ch. 3, 109–230 (Cambridge University Press, 2012). [Google Scholar]
- NOAA Climate Prediction Centre, ENSO: Recent Evolution, Current Status and Predictions. http://www.cpc.ncep.noaa.gov/products/analysis_monitoring/lanina/enso_evolution-status-fcsts-web.pdf (2016) (Date of access: 12/07/2016).
- IRI ENSO Forecast. http://iri.columbia.edu/our-expertise/climate/forecasts/enso/current/?enso_tab=enso-iri_plume (2016) (Date of access: 12/07/2016).
- Jiménez-Muñoz J. C., Mattar C., Sobrino J. A. & Malhi Y. Digital thermal monitoring of the Amazon forest: an intercomparison of satellite and reanalysis products. Int. J. Digit. Earth, doi: 10.1080/17538947.2015.1056559 (2015). [DOI] [Google Scholar]
- Clark D. A., Piper S. C., Keeling C. D. & Clark D. B. Tropical rain forest tree growth and atmospheric carbon dynamics linked to interannual temperature variation during 1984–2000. Proc. Natl. Acad. Sci. USA 100(10), 5852–5857 (2003). [DOI] [PMC free article] [PubMed] [Google Scholar]
- Galbraith D. et al. Multiple mechanisms of Amazonian forest biomass losses in three dynamic global vegetation models under climate change. New Phytol. 187, 647–665 (2010). [DOI] [PubMed] [Google Scholar]
- Aragao L. E. O. C. et al. Spatial patterns and fire response of recent Amazonian droughts. Geophys. Res. Lett. 34, L07701, doi: 10.1029/2006GL028946 (2007). [DOI] [Google Scholar]
- Foley J. A. et al. El Niño-Southern oscillation and the climate, ecosystems and rivers of Amazonia. Global Biogechemical Cycles 16, 1132 (2002). [Google Scholar]
- Cai W. et al. ENSO and greenhouse warming. Nat. Clim. Chang. 5, 849–859 (2015). [Google Scholar]
- Friedl M. A. et al. MODIS Collection 5 global land cover: Algorithm refinements and characterization of new datasets. Remote Sens. Environ. 114, 168–182 (2010). [Google Scholar]
- Dee et al. The ERA-Interim reanalysis: configuration and performance of the data assimilation system. Q. J. R. Meteorol. Soc. 173(656), 553–597 (2011). [Google Scholar]
- Poli P. et al. The data assimilation system and initial performance evaluation of the ECMWF pilot reanalysis of the 20th-century assimilating surface observations only (ERA-20C), ECMWF publications (2013).
- Morice C. P., Kennedy J. J., Rayner N. A. & Jones P. D. Quantifying uncertainties in global and regional temperature change using an ensemble of observational estimates: The HadCRUT4 dataset. J. Geophys. Res. 117, D08101 (2012). [Google Scholar]
- Jiménez-Muñoz J. C., Mattar C., Sobrino J. A. & Malhi Y. A database for the monitoring of thermal anomalies over the Amazon forest and adjacent intertropical oceans. Scientific Data 2, 150024 (2015). [DOI] [PMC free article] [PubMed] [Google Scholar]
- Wells N., Goddard S. & Hayes M. J. A self-calibrating palmer drought severity index. J. Clim. 17, 2335–2351 (2004). [Google Scholar]
- Dai A., Trenberth K. E. & Qian T. A global dataset of Palmer Drought Severity Index for 1870–2002: Relationship with soil moisture and effects of surface warming. J. Hydrometeorol. 5, 1117–1130 (2004). [Google Scholar]
- Food and Agriculture Organization, Digital soil map of the world and derived soil properties cd-rom, UNESCO (2003).
- Huffman G. J. et al. The TRMM Multisatellite Precipitation Analysis (TMPA): Quasi-Global, Multiyear, Combined-Sensor Precipitation Estimates at Fine Scales. J. Hydrometeorol. 8, 38–55 (2007). [Google Scholar]
- Adler R. F. et al. The Version 2 Global Precipitation Climatology Project (GPCP) Monthly Precipitation Analysis (1979-Present). J. Hydrometeor. 4, 1147–1167 (2003). [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.