Rare ground data confirm significant warming and drying in western equatorial Africa

Bush, Emma R; Jeffery, Kathryn J.; Tutin, Caroline E. G.; Musgrave, Ruth; Moussavou, Ghislain; Mihindou, Vianet; Malhi, Yadvinder; Lehmann, David; Ndong, Josué Edzang; Makaga, Loïc; Abernethy, Katharine

doi:10.7717/peerj.8732

Cited by 24 publications

(24 citation statements)

References 65 publications

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“…The results in Table 1 agree well with those of Nicholson et al (2019), which found CHIRPS2 and PERSIANN-CDR to be more accurate than TRMM and GPCC in the Congo Basin after 1998. Prior work has also demonstrated that CHIRPS2 is among the best P products available for central Africa and outperforms TRMM and PERSIANN-CDR on a monthly basis (Dembélé and Zwart, 2016;Camberlin et al, 2019;Nicholson et al, 2019), consistent with the results in Table 1. Given the decreasing availability of Congolese rain gauge data in the GPCC database and the difficulty of measuring P with satellite remote sensing in central Africa (McCollum et al, 2000;Yin and Gruber, 2010;Awange et al, 2016;Nicholson et al, 2018), it is not surprising that the GPCC-based products generally displayed higher errors.…”

Section: Triple Collocation Of Precipitation Datasetssupporting

confidence: 84%

“…While PER-SIANN is also available without the GPCC gauge corrections that make PERSIANN-CDR so similar to GPCC v7 and TRMM 3B43 over the Congo Basin (Nguyen et al, 2018), it was not used here because it severely overestimates P across Africa (Beighley et al, 2011;Thiemig et al, 2012). Several recent studies have found that TRMM Version 7 3B43 and PERSIANN-CDR both perform reasonably well over central 4192 M. W. Burnett et al: Data-driven estimates of evapotranspiration and its controls in the Congo Basin Africa (Munzimi et al, 2015;Awange et al, 2016;Camberlin et al, 2019).…”

Section: Water Balance Data Sourcesmentioning

confidence: 99%

“…To that end, the Climate Hazards InfraRed Precipitation with Station data version 2.0 (CHIRPS2) product, which uses two thermal infrared datasets and interpolated gauge data, was also included as a more independent dataset (Funk et al, 2015a). The CHIRPS2 product was recently found to be among the most accurate rainfall datasets on monthly timescales within the Congo Basin (Camberlin et al, 2019).While CHIRPS2 does incorporate some gauge data that overlap with the GPCC product, it is not scaled to fit GPCC data to the same extent as TRMM 3B43 or PERSIANN-CDR are over central Africa (Nicholson et al, 2019) -in fact, the near-total lack of rain gauges within the basin in both CHIRPS2 and GPCC leads to a low correlation between the two datasets within the study area (Funk et al, 2015a), indicating the P datasets maintain a high degree of independence. Finally, a recent gauge-based dataset developed for the Congo Basin, NIC131-gridded, served as another independent precipitation data source with coverage through 2014 (Nicholson et al, 2018).…”

Section: Water Balance Data Sourcesmentioning

confidence: 99%

“…Likewise, microwave backscatter data from large areas of the Congo's evergreen forests imply canopy biomass and/or water content peak during JJA and, to a lesser extent, DJF (Guan et al, 2013;. But phenological observations from Gabon indicate that new leaf growth is sup-pressed during JJA and that the full mature-leaf tree canopies common in JJA contain an elevated fraction of senescing leaves, so dry-season backscatter peaks in Congolese evergreen forests may not be attributable to widespread leafflushing events (Bush, 2018). Overall, the phenological synchronicity of leaf-out events appears to be low in the evergreen forests of central Africa (Couralet et al, 2013;Bush, 2018), so the magnitude and hydrologic effects of evergreen leaf flushing are probably smaller and more temporally distributed in the evergreen forests than in the deciduous woodlands of the basin.…”

Section: Leaf-age-related Wue Variationsmentioning

confidence: 99%

“…2016; Dezfuli, 2017). Such shifts are particularly concerning because Africa's tropical rainforests are already significantly drier than other humid tropical forests and exist at the climatic threshold of conversion from evergreen to deciduous trees (Guan et al, 2015;Philippon et al, 2019;Bush et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Data-driven estimates of evapotranspiration and its controls in the Congo Basin

Burnett

Quetin

Konings

2020

Hydrol. Earth Syst. Sci.

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Abstract. Evapotranspiration (ET) from tropical forests serves as a critical moisture source for regional and global climate cycles. However, the magnitude, seasonality, and interannual variability of ET in the Congo Basin remain poorly constrained due to a scarcity of direct observations, despite the Congo being the second-largest river basin in the world and containing a vast region of tropical forest. In this study, we applied a water balance model to an array of remotely sensed and in situ datasets to produce monthly, basin-wide ET estimates spanning April 2002 to November 2016. Data sources include water storage changes estimated from the Gravity Recovery and Climate Experiment (GRACE) satellites, in situ measurements of river discharge, and precipitation from several remotely sensed and gauge-based sources. An optimal precipitation dataset was determined as a weighted average of interpolated data by Nicholson et al. (2018), Climate Hazards InfraRed Precipitation with Station data version 2 (CHIRPS2) , and the Precipitation Estimation from Remotely Sensed Information using Artificial Neural Networks–Climate Data Record product (PERSIANN-CDR), with the relative weights based on the error magnitudes of each dataset as determined by triple collocation. The resulting water-balance-derived ET (ETwb) features a long-term average that is consistent with previous studies (117.2±3.5 cm yr−1) but displays greater seasonal and interannual variability than seven global ET products. The seasonal cycle of ETwb generally tracks that of precipitation over the basin, with the exception that ETwb is greater in March–April–May (MAM) than in the relatively wetter September–October–November (SON) periods. This pattern appears to be driven by seasonal variations in the diffuse photosynthetically active radiation (PAR) fraction, net radiation (Rn), and soil water availability. From 2002 to 2016, Rn, PAR, and vapor-pressure deficit (VPD) all increased significantly within the Congo Basin; however, no corresponding trend occurred in ETwb. We hypothesize that the stability of ETwb over the study period despite sunnier and less humid conditions may be due to increasing atmospheric CO2 concentrations that offset the impacts of rising VPD and irradiance on stomatal water use efficiency (WUE).

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