Vertical profile of the clear-sky aerosol direct radiative effect in an Alpine valley, by the synergy of ground-based measurements and radiative transfer simulations

Fasano, Gabriele; Diémoz, Henri; Fountoulakis, Ilias; Cassardo, Claudio; Kudo, Rei; Siani, Anna Maria; Ferrero, Luca

doi:10.1007/s42865-021-00041-w

Cited by 7 publications

(4 citation statements)

References 44 publications

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“…Thus, we use the same radiative calculations to represent the aerosol effect in the different SST scenarios. We note that the estimated RHR presented in Figure 1b aligns qualitatively in magnitude and vertical structure with observed RHR profiles from previous studies on absorbing aerosols (Z. Wang et al., 2018; Lu et al., 2020; Fasano et al., 2021; Cochrane et al., 2022).…”

Section: Methodssupporting

confidence: 85%

The Potential of Absorbing Aerosols to Enhance Extreme Precipitation

Dagan,

Eytan

2024

Geophysical Research Letters

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Understanding the impact of various climate forcing agents, such as aerosols, on extreme precipitation is socially and scientifically vital. While anthropogenic absorbing aerosols influence Earth's energy balance and atmospheric convection, their role in extreme events remains unclear. This paper uses convective‐resolving radiative‐convective‐equilibrium simulations, with fixed solar radiation, to investigate the influence of absorbing aerosols on extreme precipitation comprehensively. Our findings reveal an underappreciated mechanism through which absorbing aerosols can, under certain conditions, strongly intensify extreme precipitation. Notably, we demonstrate that a mechanism previously reported for much warmer (hothouse) climates, where intense rainfall alternates with multi‐day dry spells, can operate under current realistic conditions due to absorbing aerosol influence. This mechanism operates when an aerosol perturbation shifts the lower tropospheric radiative heating rate to positive values, generating a strong inhibition layer. Our work highlights an additional potential effect of absorbing aerosols, with implications for climate change mitigation and disaster risk management.

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Section: Methodssupporting

confidence: 85%

The Potential of Absorbing Aerosols to Enhance Extreme Precipitation

Dagan,

Eytan

2024

Geophysical Research Letters

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“…Previous lidar measurements in the Alps by a ground-based scanning system during VOTALP have allowed us to identify the two aerosol layers associated with inversions typically induced by local and regional orography, as well as horizontal inhomogeneities in aerosol concentrations at the opening of the Mesolcina valley near Grono, Switzerland [25]. More recently, a ground-based micropulse lidar was used in the Italian valley of Aosta to quantify, for the first time, the direct radiative effect of aerosols during two cases-one with local pollution, and one during a dust transport event in June 2019 [26]. Nonetheless, the three-dimensional distribution of pollutants was only previously investigated during POVA in the Chamonix and Maurienne valleys [17], coupling in situ airborne and lidar measurements to highlight their sources, along with urban heat island effects.…”

Section: Introductionmentioning

confidence: 99%

Lidar Profiling of Aerosol Vertical Distribution in the Urbanized French Alpine Valley of Annecy and Impact of a Saharan Dust Transport Event

Chazette

Totems

2023

Remote Sensing

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The vertical aerosol layering of the troposphere is poorly documented in mountainous regions, particularly in the Alpine valleys, which are influenced by valley and mountain winds. To improve our knowledge of particulate matter trapped in the Annecy valley, synergetic measurements performed by a ground-based meteorological Raman lidar and a Rayleigh-Mie lidar aboard an ultralight aircraft were implemented as part of the Lacustrine-Water vApor Isotope inVentory Experiment (L-WAIVE) over Lake Annecy. These observations were complemented by satellite observations and Lagrangian modeling. The vertical profiles of aerosol optical properties (e.g., aerosol extinction coefficient (AEC), lidar ratio (LR), particle linear depolarization ratio (PDR)) are derived from lidar measurements at 355 nm during the period between 13 and 22 June 2019. The background aerosol content with an aerosol optical thickness (AOT) of 0.10 ± 0.05, corresponding to local–regional conditions influenced by anthropogenic pollution, has been characterized over the entirety of Lake Annecy thanks to the mobile ultralight payload. The aerosol optical properties are shown to be particularly variable over time in the atmospheric column, with mean LRs (PDRs) varying between 40 ± 8 and 115 ± 15 sr (2 ± 1 and 35 ± 2%). Those conditions can be disturbed by air masses that have recirculated over the valley, as well as by contributions from neighboring valleys. We have observed an important disruption in the atmospheric aerosol profiles by the arrival of an exceptionally dry air mass (RH ~ 30%), containing aerosols identified as coming from the Great Western Erg (AOT ~ 0.5, LR = 65 ± 10 sr, PDR = 20–35%) in the Sahara. These desert dust particles are shown to influence the entire atmospheric column in the Annecy valley. Such an experimental approach, coupling upward and downward lidar and spaceborne observation/Lagrangian modelling, was shown to be of significant interest for the long-term monitoring of the evolution of aerosol loads over deep valleys. It allows a better understanding of the influence of dust storms in the presence of severe convective weather processes.

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“…Microplastics can travel very long distances from their sources and have been detected at very high altitudes, on the order of 3 km, in the atmosphere [38,39]. Fasano et al [40] showed that even over a pristine alpine region, transported Saharan dust can increase atmospheric heating rates (HR) by more than 1 K/day (relative to aerosol-free atmosphere), and at the same time have a negative radiative effect at the top and bottom of the atmosphere. In such regions (i.e., alpine valleys) changes in atmospheric heating have an immediate impact on the climate of the slopes and are considered among the possible drivers of elevation-dependent warming (EDW) [41,42].…”

Section: Introductionmentioning

confidence: 99%

Effect of Aerosol Vertical Distribution on the Modeling of Solar Radiation

et al. 2022

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Default aerosol extinction coefficient profiles are commonly used instead of measured profiles in radiative transfer modeling, increasing the uncertainties in the simulations. The present study aimed to determine the magnitude of these uncertainties and contribute towards the understanding of the complex interactions between aerosols and solar radiation. Default, artificial and measured profiles of the aerosol extinction coefficient were used to simulate the profiles of different radiometric quantities in the atmosphere for different surface, atmospheric, and aerosol properties and for four spectral bands: ultraviolet-B, ultraviolet-A, visible, and near-infrared. Case studies were performed over different areas in Europe and North Africa. Analysis of the results showed that under cloudless skies, changing the altitude of an artificial aerosol layer has minor impact on the levels of shortwave radiation at the top and bottom of the atmosphere, even for high aerosol loads. Differences of up to 30% were, however, detected for individual spectral bands. Using measured instead of default profiles for the simulations led to more significant differences in the atmosphere, which became very large during dust episodes (10–60% for actinic flux at altitudes between 1 and 2 km, and up to 15 K/day for heating rates depending on the site and solar elevation).

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Vertical profile of the clear-sky aerosol direct radiative effect in an Alpine valley, by the synergy of ground-based measurements and radiative transfer simulations

Cited by 7 publications

References 44 publications

The Potential of Absorbing Aerosols to Enhance Extreme Precipitation

The Potential of Absorbing Aerosols to Enhance Extreme Precipitation

Lidar Profiling of Aerosol Vertical Distribution in the Urbanized French Alpine Valley of Annecy and Impact of a Saharan Dust Transport Event

Effect of Aerosol Vertical Distribution on the Modeling of Solar Radiation

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