Diurnal cycle of the South Pacific Convergence Zone in 30 years of satellite images

Haffke, C. M.; Magnúsdóttir, Guðrún

doi:10.1002/2015jd023436

Cited by 10 publications

(4 citation statements)

References 33 publications

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“…From the 5-day averaged CTH pattern ( Fig. 7), two peaks in the median CTH and the accompanying semidiurnal cycles are identified, as consistent with current consensus (Kossin 2002;Dunion et al 2014;Haffke et al 2015). The corresponding quantitative identifications of the CTH cycles on subdaily timescales are shown in Fig.…”

Section: Resultssupporting

confidence: 59%

Characteristics of Diurnal Pulses Observed in Typhoon Atsani Using Retrieved Cloud Property Data

Wang

Iwabuchi

Takahashi

2019

SOLA

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Using several cloud properties retrieved from the Himawari-8 satellite, combined with the best track storm center information, the temporal-spatial features of tropical cyclone (TC) diurnal pulses in 2015 Super Typhoon Atsani (T1516) are coherently depicted. To demonstrate the radially outward transition processes of the diurnal pulses from one cloud type to another, we divided high clouds into three types: opaque high cloud (OHC), cirrostratus (Cs), and cirrus (Ci). Two alternatively appeared peaks in cloud top height (CTH) within the storm central area and their corresponding outward pulses are identified. The first pulse covers a 24-hour period, it starts at ~0500−0700 local solar time (LST), with a gradual transition from OHC to Cs, then ends in Ci at around 0400 LST. The second pulse lasts for half a day and limited within 1000 km from the storm center. When the first CTH pulse ends in OHC, Cs, and Ci, their cloud fractional coverage and the outward expansion of large cloud optical thickness also reach maximum accordingly.

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Section: Resultssupporting

confidence: 59%

Characteristics of Diurnal Pulses Observed in Typhoon Atsani Using Retrieved Cloud Property Data

Wang

Iwabuchi

Takahashi

2019

SOLA

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“…A single LST pixel corresponding to the location of the in-situ measurements was extracted from the imagery for each of the distinct Landsat 8 profile records and compared against the in-situ measurements at a time coincident with the Landsat 8 overpass. LST from in-situ locations was calculated following Equations (1) and (4) (see Section 2.2), making use of air temperature and humidity that was collected by the weather stations collocated with the radiometer data, as well as emissivity data following Equation (2). Figures 3 and 4 illustrate the differences between the Landsat-based LST estimates and in-situ LST for each of the studied land covers.…”

Section: Evaluation Against In-situ Observationsmentioning

confidence: 99%

“…Apart from being a fundamental variable in quantifying elements of the surface energy budget [1], LST has been used to study ocean-atmosphere interactions [2], to track global warming and climate change impacts [3,4], as well as being widely used in studies of vegetation monitoring [5], drought persistence [6] and urban climate assessments [7]. LST also plays a critical role in linking the water and energy cycles through its relationship with surface heat fluxes [8].…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems

2017

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Abstract:The land surface temperature (LST) represents a critical element in efforts to characterize global surface energy and water fluxes, as well as being an essential climate variable in its own right. Current satellite platforms provide a range of spatial and temporal resolution radiance data from which LST can be determined. One of the most complete records of data comes via the Landsat series of satellites, which provide a continuous sequence that extends back to 1982. However, for much of this time, Landsat thermal data were provided through a single broadband thermal channel, making surface temperature retrieval challenging. To fully exploit the valuable time-series of thermal information that is available from these satellites requires efforts to better describe and understand the accuracy of temperature retrievals. Here, we contribute to these efforts by examining the impact of atmospheric correction on the estimation of LST, using atmospheric profiles derived from a range of in-situ, reanalysis, and satellite data. Radiance data from the thermal infrared (TIR) sensor onboard Landsat 8 was converted to LST by using the MODTRAN version 5.2 radiative transfer model, allowing the production of an LST time series based upon 28 Landsat overpasses. LST retrievals were then evaluated against in-situ thermal measurements collected over an arid zone farmland comprising both bare soil and vegetated surface types. Atmospheric profiles derived from AIRS, MOD07, ECMWF, NCEP, and balloon-based radiosonde data were used to drive the MODTRAN simulations. In addition to examining the direct impact of using various profile data on LST retrievals, randomly distributed errors were introduced into a range of forcing variables to better understand retrieval uncertainty. Results indicated differences in LST of up to 1 K for perturbations in emissivity and profile measurements, with the analysis also highlighting the challenges in modeling aerosol optical depth (AOD) over arid lands and its impact on the TIR bands. Days with high AOD content (AOD > 0.5) in the evaluation study seem to consistently underestimate in-situ LSTs by 1-2 K, suggesting that MODTRAN is unable to accurately simulate the aerosol conditions for the TIR bands. Comparisons between available in-situ and Landsat 8 derived LST illustrate a range of seasonal and land surface dynamics and provide an assessment of retrieval accuracy throughout the nine-month long study period. In terms of the choice of atmospheric profile, when excluding the in-situ data, results show a mean absolute range of between 1.2 K to 1.8 K over bare soil and 3.3 K to 3.8 K over alfalfa for the different meteorological forcing, with the AIRS profile providing the best reproduction over the studied arid land irrigation region.

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“…In contrast, over the Atlantic and eastern Pacific oceans, the ITCZ does not migrate seasonally between the two hemispheres and resides north of the equator during most of the year (Philander et al, ). In the western Pacific, apart from the northern ITCZ, the so‐called south Pacific convergence zone (SPCZ) is also prominent from the equatorial region north of Australia poleward and eastward toward 30°S in the central Pacific, with seasonally varying strength, which picks during boreal winter (see Berry & Reeder, ; Haffke & Magnusdottir, , ; Widlansky et al, ). It should be also noted that although the ITCZ in the northern Pacific and Atlantic oceans is mainly a zonal feature, the SPCZ as well as the south Indian Ocean convergence zone (Cook, , ) and the south Atlantic convergence zone (Carvalho et al, ) are diagonally oriented.…”

Section: Introductionmentioning

confidence: 99%

A Multivariate Probabilistic Framework for Tracking the Intertropical Convergence Zone: Analysis of Recent Climatology and Past Trends

Mamalakis

Foufoula‐Georgiou

2018

Geophysical Research Letters

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Due to its importance for water availability in the tropics and subtropics, efficient tracking of the seasonal and long‐term shifts of the intertropical convergence zone (ITCZ) is of great value. Current approaches, which are based on tracking changes in the annual mean of single variables, ignore the intra‐annual dynamics, while more sophisticated methods are computationally intensive. Here we propose a new probabilistic framework to track the ITCZ, which is based on tracking the location of maximum precipitation and minimum outgoing longwave radiation in overlapping longitudinal windows. Our framework is seasonally and longitudinally explicit, allows for joint consideration of multiple variables to define the ITCZ, and is flexible in its implementation, thus, it can be used in analyses of different scales and scopes. We apply our framework to analyze the recent climatology of the ITCZ and report a southward trend in its location over central Pacific in the late twentieth century.

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Diurnal cycle of the South Pacific Convergence Zone in 30 years of satellite images

Cited by 10 publications

References 33 publications

Characteristics of Diurnal Pulses Observed in Typhoon Atsani Using Retrieved Cloud Property Data

Characteristics of Diurnal Pulses Observed in Typhoon Atsani Using Retrieved Cloud Property Data

Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems

A Multivariate Probabilistic Framework for Tracking the Intertropical Convergence Zone: Analysis of Recent Climatology and Past Trends

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