Regional Intensification of the Tropical Hydrological Cycle During ENSO

Stephens, Graeme L.; Hakuba, Maria Z.; Webb, Mark J.; Lebsock, Matthew; Yue, Qing; Kahn, Brian H.; Hristova-Veleva, S. M.; Rapp, A. D.; Stubenrauch, C.; Elsaesser, Gregory S.; Slingo, Julia

doi:10.1029/2018gl077598

Cited by 32 publications

(23 citation statements)

References 47 publications

(60 reference statements)

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“…For the ENSO region, we also find teleconnections, meaning that there are high correlations with positive and negative signs throughout the region as is exemplarily shown in Figure (note that we show correlation coefficients [r] and not squared ones [ R 2 ] as used for the calculation of δ ). The finding of positive and negative correlations of SSR in the ENSO region is in line with previous studies that focused on the impact of ENSO on SSR (e.g., Pavlakis et al, ; Pinker et al, ; Stephens et al, ). As these studies either used modeled SSR, satellite‐derived SSR estimates with coarse resolution, or SSR from reanalysis, our finding can be counted as additional evidence based on high‐resolution satellite data for the strong influence of ENSO on SSR.…”

Section: Representativeness: Quantitative Estimatessupporting

confidence: 92%

From Point to Area: Worldwide Assessment of the Representativeness of Monthly Surface Solar Radiation Records

Schwarz¹,

Folini²,

Hakuba

et al. 2018

JGR Atmospheres

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The representativeness of surface solar radiation (SSR) point observations is an important issue when using them in combination with gridded data. We conduct a comprehensive near‐global (50°S to 55°N) analysis on the representativeness of SSR point observations on the monthly mean time scale. Thereto, we apply the existing concepts of decorrelation lengths (δ), spatial sampling biases (β), and spatial sampling errors (ε) to three high‐resolution gridded monthly mean SSR data sets (CLARA, SARAH‐P, and SARAH‐E) provided by the Satellite Application Facility on Climate Monitoring. While δ quantifies the area for which a point observation is representative, β and ε are uncertainty estimates with respect to the 1‐degree reference grid (G). For this grid we find a near‐global average δG=3.4°, βG=1.4 W/m2, and εG=7.6 W/m2 with substantial regional differences. Disregarding tropical, mountainous, and some coastal regions, monthly SSR point observations can largely be considered representative of a 1‐degree grid. Since ε is an uncorrectable error the total uncertainty when combining point with 1‐degree gridded data is roughly 40% higher than the uncertainty of station‐based SSR measurements alone if a rigorous bias correction is applied. Cloud cover and terrain data can at maximum explain 50% of the patterns of the representativeness metrics. We apply our methodology to the stations of the Baseline Surface Radiation Network. Overall, this study shows that representativeness is strongly dependent on local conditions and that all three metrics (δ, β, and ε) must be considered for a comprehensive assessment of representativeness.

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Section: Representativeness: Quantitative Estimatessupporting

confidence: 92%

From Point to Area: Worldwide Assessment of the Representativeness of Monthly Surface Solar Radiation Records

Schwarz¹,

Folini²,

Hakuba

et al. 2018

JGR Atmospheres

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“…The well-documented (Wylie et al, 2005;King et al, 2013;Stubenrauch et al, 2013) spatial distributions of ice clouds with maxima in the tropics and extratropical storm tracks and minima in the subtropical gyres are shown in Fig. 1.…”

Section: Atmospheric Infrared Sounder (Airs)mentioning

confidence: 99%

“…Secular changes in the joint histograms themselves, and, furthermore, changes in the frequency of occurrence within the joint histogram bins, must be quantified to deduce if trends or variability in CWV, rain occurrence, surface wind speed, and other relevant geophysical parameters such as low-level convergence (e.g. Stephens et al, 2018) could explain in part or whole secular trends in r ei .…”

Section: Summary Conclusion and Outlookmentioning

confidence: 99%

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Ice cloud microphysical trends observed by the Atmospheric Infrared Sounder

et al. 2018

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Abstract. We use the Atmospheric Infrared Sounder (AIRS) version 6 ice cloud property and thermodynamic phase retrievals to quantify variability and 14-year trends in ice cloud frequency, ice cloud top temperature (T ci ), ice optical thickness (τ i ) and ice effective radius (r ei ). The trends in ice cloud properties are shown to be independent of trends in information content and χ 2 . Statistically significant decreases in ice frequency, τ i , and ice water path (IWP) are found in the SH and NH extratropics, but trends are of much smaller magnitude and statistically insignificant in the tropics. However, statistically significant increases in r ei are found in all three latitude bands. Perturbation experiments consistent with estimates of AIRS radiometric stability fall significantly short of explaining the observed trends in ice properties, averaging kernels, and χ 2 trends. Values of r ei are larger at the tops of opaque clouds and exhibit dependence on surface wind speed, column water vapour (CWV) and surface temperature (T sfc ) with changes up to 4-5 µm but are only 1.9 % of all ice clouds. Non-opaque clouds exhibit a much smaller change in r ei with respect to CWV and T sfc . Comparisons between DARDAR and AIRS suggest that r ei is smallest for singlelayer cirrus, larger for cirrus above weak convection, and largest for cirrus above strong convection at the same cloud top temperature. This behaviour is consistent with enhanced particle growth from radiative cooling above convection or large particle lofting from strong convection.

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“…Their study highlights the shifting of the intertropical convergence zone and the South Pacific convergence zone, which establish a major change in the spatial distribution of rainfall anomalies. Across the tropics, the impact of ENSO is largely associated with changes in rainfall anomalies (Stephens et al, 2018) and the consequent development of drought and wetter than normal conditions depending on the region and the phase of ENSO; with an identified opposite effect of ENSO on rainfall over land and ocean (Neelin, Chou, & Su, 2003). In the maritime continent, ENSO has been found to FIGURE 1 Literature search of published studies (ISI Web of Science) combining the keywords "isotopes" and "Europe"/"North America"/"Tropics" from 2000 to 2018 leverage air-sea interactions and generate a remotely driven wind forcing, which can lead to a local feedback mechanism between the winds and the SST anomalies, resulting in the development of a dry season (Hendon, 2003).…”

Section: Atmosphere-ocean Processesmentioning

confidence: 99%