Trend in the atmospheric heat source over the central and eastern Tibetan Plateau during recent decades: Comparison of observations and reanalysis data

Wang, Meirong; Zhou, Siyang; Duan, Anmin

doi:10.1007/s11434-011-4838-8

Cited by 45 publications

(32 citation statements)

References 25 publications

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“…Such changes have invited crucial questions, such as how atmospheric variations and surface changes impact the SRB over the TP, how the decadal dimming and brightening affect the environment and climate [ Wild , ], how the SRB over the TP responds to rapid warming [ Qin et al ., ], and how the SRB and latent and sensible heat fluxes over the TP are related to the East Asian monsoon climate [ Duan et al ., ; Wu et al ., ]. However, few studies have attempted spatiotemporal characterization of the SRB components over the entire TP in recent decades, for several reasons: limited sites for ground measurement [ Stone , ; Bookhagen , ], poor accuracy of remote sensing products [ Pinker et al ., ], and inconsistent trends derived from multiple reanalysis products [ Tang et al ., ; Wang et al ., ]. Part 1 of this two‐paper series described an effective data fusion method that synthesized ground observations, reanalysis products, and remote sensing data sets at 0.5° spatial resolution from July 1983 to December 2007 with RMSEs <20 Wm −2 for radiation fluxes and 0.05 for albedo.…”

Section: Introductionmentioning

confidence: 99%

Characterizing the surface radiation budget over the Tibetan Plateau with ground‐measured, reanalysis, and remote sensing data sets: 2. Spatiotemporal analysis

Shi

Liang

2013

JGR Atmospheres

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[1] Recent progress in observation and modeling studies indicates that the Tibetan Plateau (TP) has been experiencing solar dimming coincident with changes of surface and atmospheric conditions since the early 1980s. However, changes and variability of the surface radiation budget over the entire Tibetan Plateau have rarely been analyzed in association with meteorological observations. Taking into consideration the limitations in ground measurements, reanalysis products, and remote sensing products, this paper applies the fused data (described in Part 1 of this two-paper series) to analyze the seasonal and annual spatial pattern and temporal variation in the surface radiation budget (SRB) over the TP from 1984 to 2007. The climatology and interannual variability of five SRB components-downward shortwave irradiance, albedo, downward longwave flux, upward longwave flux, and net all-wave radiation-are presented and analyzed in conjunction with atmospheric (cloud cover, water vapor) and surface (temperature, snow cover, normalized difference vegetation index) conditions over the Tibetan Plateau. Over the entire Tibetan Plateau, regardless of the increase of downward longwave radiation that counteracts the increase of upward longwave radiation, the interaction of solar dimming with changes of surface albedo has dominated the marked decrease of all-wave net radiation since the mid-1980s. This result indicates that the weakening and strengthening of the relationship between the components of SRB and the correlated variables of atmospheric or surface conditions exhibit a seasonal dependency over the TP. Moreover, most peaks and drops in the SRB anomalies are consistent to variations in two dominant variables.Citation: Shi, Q., and S. Liang (2013), Characterizing the surface radiation budget over the Tibetan Plateau with ground-measured, reanalysis, and remote sensing data sets: 2. Spatiotemporal analysis,

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Section: Introductionmentioning

confidence: 99%

Characterizing the surface radiation budget over the Tibetan Plateau with ground‐measured, reanalysis, and remote sensing data sets: 2. Spatiotemporal analysis

Shi

Liang

2013

JGR Atmospheres

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“…Increasing greenhouse gas can significantly influence the global and regional dust cycle through affecting the climate, veg- 25 etation and dust-climate feedbacks although there exists large uncertainty in the response of the global dust loading to future climate change (Harrison et al, 2001;Tegen et al, 2004;Mahowald et al, 2006;Kok et al, 2018). Additionally, the surface sensible flux over TP exhibits a remarkable weakening trend under global warming, induced primarily by weakened surface wind speeds (Duan et al, 2011;Wang et al, 2012;Yang et al, 2014). Our study shows the importance of the TPSH on the change in East Asian dust cycle through affecting the westerly winds.…”

Section: Discussionmentioning

confidence: 99%

Modulation of surface sensible heating over the Tibetan Plateau on the interannual variability of East Asian dust cycle

Xie¹,

Duan²,

Shi³

et al. 2020

Preprint

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Previous observational evidence and numerical simulations have revealed that the surface sensible heating in MAM (March-April-May) over the Tibetan Plateau (TPSH) can affect the Asian regional hydrological cycle, surface energy balance, and climate through altering atmospheric heat source of the Tibetan Plateau (TP). This study aims to investigate the impacts of MAM TPSH on the interannual variability of East Asian dust cycle by use of CAM4-BAM (version 4 of the Community Atmosphere Model coupled to a bulk aerosol model), the MERRA-2 (version 2 of the Modern Era Retrospective-Analysis for 5Research and Applications) surface dust concentration, and TPSH measurements. Our simulations show that the surface dust concentrations over the East Asian dust source region (EA) and over the northwestern Pacific (NP) in MAM are significantly positively correlated with TPSH, with regionally averaged correlation coefficients of 0.49 for EA and 0.44 for NP. Similar positive correlations are also shown to exist between the MAM TPSH measurements averaged over the 73 observation sites and the surface dust concentration from MERRA-2. Simulation-based comparisons between strongest and weakest TPSH years 10 reveal that, the MAM surface dust concentration in the strongest TPSH years increases with relative differences of 13.1% over EA and 36.9% over NP. These corresponding differences are found in MERRA-2 with 22.9% and 13.3% over EA and NP, respectively. Further simulated results show that the processes of whole dust cycles (e.g., dust loading, emission, and transport, as well as dust depositions) are also significantly enhanced during the strongest TPSH yeas over EA and NP. Through enhancing the TP heat source, stronger TPSH in MAM generates an anticyclonic anomaly in middle and upper troposphere over TP and 15 over the downstream Pacific region, respectively. These atmospheric circulation anomalies induced by the increased TPSH result in increasing the westerly winds over both EA and NP, which in turn increases dust emissions over the dust source, and dust transports over these two regions, as well as the regional dust cycles. These results suggest that addressing the East Asian dust changes in the future climates require considering not only increasing greenhouse gas emissions but also the variations of the TP's heat source under global warming.

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“…According to previous studies (Monin and Obukhov 1954, Duan and Wu 2008, Wang et al 2012, Duan et al 2018b, SH can be calculated by the following equation:…”

Section: Methodsmentioning

confidence: 99%

“…In recent years, the SH over the TP has been proved to be undergoing a decreasing trend, especially in spring season (Duan and Wu 2008, Wang et al 2012, Wang and Ma 2018. Duan and Wu (2008) suggested that this weakening trend in SH was induced mainly by the steadily decreased surface wind speed, which was linked to climate warming (Duan and Wu 2009).…”

Section: Introductionmentioning

confidence: 99%

Recent recovery of the boreal spring sensible heating over the Tibetan Plateau will continue in CMIP6 future projections

Wang

Chen

et al. 2019

Environ. Res. Lett.

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The spring sensible heating (SH) over the Tibetan Plateau (TP) serves as a huge 'air pump', significantly influencing the Asian summer monsoon, has experienced a decreasing trend. However, it remains unclear whether this decline will continue. Therefore, we here examine the long-term trends of spring SH over the central and eastern TP (CETP) based on a meteorological station-based calculated SH dataset, and CMIP6 multi-model simulations. These two sources confirmed the previous finding that the SH peaks in May. Further, we find that the declining SH was replaced by a fast recovery after approximate 2000 in the station-based SH. This is to some extent verified by the historical simulations of CMIP6 models. Importantly, CMIP6 future projections suggest that this increasing trend will continue, and get stronger with higher radiative forcing from SSP126 to SSP585. Mechanism analysis indicates that the previous decreasing trend in SH was mainly caused by the decline of 10 m wind speed, while the recent and future increasing trend results from the rising ground-air temperature difference. We suggest that this increasing trend of spring SH over the CETP may serve as an alternative driver for the enhancement of the East Asian summer monsoon in the future.

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Trend in the atmospheric heat source over the central and eastern Tibetan Plateau during recent decades: Comparison of observations and reanalysis data

Cited by 45 publications

References 25 publications

Characterizing the surface radiation budget over the Tibetan Plateau with ground‐measured, reanalysis, and remote sensing data sets: 2. Spatiotemporal analysis

Characterizing the surface radiation budget over the Tibetan Plateau with ground‐measured, reanalysis, and remote sensing data sets: 2. Spatiotemporal analysis

Modulation of surface sensible heating over the Tibetan Plateau on the interannual variability of East Asian dust cycle

Recent recovery of the boreal spring sensible heating over the Tibetan Plateau will continue in CMIP6 future projections

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