Enhanced extinction of visible radiation due to hydrated aerosols in mist and fog

Elías, T.; Dupont, Jean-Charles; Hammer, E.; Hoyle, C. R.; Haeffelin, Martial; Burnet, Frédéric; Jolivet, Dominique

doi:10.5194/acp-15-6605-2015

Cited by 24 publications

(34 citation statements)

References 46 publications

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“…During the winters of 2010 to 2013, specific instrumentation were deployed for the PreViBOSS project (Elias et al, 2012) to provide continuous observation of aerosol and fog microphysics. The experimental setup was already presented in Burnet et al (2012), Hammer et al (2014), Elias et al (2015) and Dupont et al (2016). The instruments used in this study are listed in Table 1.…”

Section: Instrumentationmentioning

confidence: 99%

“…The WELAS-2000 (hereafter referred to as WELAS) provides particle size spectrum between 0.4 and 40 µm in diameter according to the constructor. However, the detection efficiency decreases drastically below ∼ 1 µm (Heim et al, 2008;Elias et al, 2015), resulting in a strong underestimation of the concentration of the submicronic particles. Hammer et al (2014) choose to consider only data with diameters larger than 1.4 µm.…”

Section: Instrumentationmentioning

confidence: 99%

“…Currently, their definition mainly deals with the instrumentation limitation that generally begins at 2 µm in diameter to measure droplet size distribution. However, Hammer et al (2014) and Elias et al (2015) experimentally determined threshold diameter higher than 2 µm to characterize droplets. As the smallest hydrated particles are more numerous, considering a smallest threshold diameter could lead to a significant overestimation of the droplet concentration.…”

Section: Introductionmentioning

confidence: 99%

“…Burnet et al (2012) have shown that, in terms of droplet number concentration and effective diameter, the microphysical properties of fog events sampled at SIRTA present a large variability. Elias et al (2015) examined the data collected during November 2011 and assessed the contribution of hydrated aerosols that led to the extinction of the visible radiation in the mist-fog-mist cycle. Hammer et al (2014) focused on the activation properties of developed fog events observed during the winter of 2012/2013, but they did not provide activated particle concentrations values.…”

Section: Introductionmentioning

confidence: 99%

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Experimental study of the aerosol impact on fog microphysics

et al. 2019

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Abstract. Comprehensive field campaigns dedicated to fog life cycle observation were conducted during the winters of 2010–2013 at the Instrumented Site for Atmospheric Remote Sensing Research (SIRTA) observatory in a suburb of Paris. In order to document their properties, in situ microphysical measurements collected during 23 fog events induced by both radiative cooling and stratus lowering are examined here. They reveal large variability in number, concentration and size of both aerosol background before the fog onset and fog droplets according to the different cases. The objective of this paper is to evaluate the impact of aerosol particles on the fog microphysics. To derive an accurate estimation of the actual activated fog droplet number concentration Nact, we determine the hygroscopicity parameter κ, the dry and the wet critical diameter and the critical supersaturation for each case by using an iterative procedure based on the κ-Köhler theory that combines cloud condensation nuclei (CCN), dry particle and droplet size distribution measurements. Our study reveals low values of the derived critical supersaturation occurring in fog with a median of 0.043 %. Consequently, the median dry and wet activation diameters are 0.39 and 3.79 µm, respectively, leading to a minor fraction of the aerosol population activated into droplets. The corresponding Nact values are low, with median concentrations of 53.5 and 111 cm−3 within the 75th percentile. The activated fraction of aerosols exhibits remarkably low correlation with κ values, which reflects the chemical composition of the aerosols. On the contrary, the activated fraction exhibits a strong correlation with the inferred critical diameter throughout the field campaigns. This suggests that the variability in the activated fraction is mostly driven by particle size, while variations in aerosol composition are of secondary importance. Moreover, our analysis suggests that the supersaturation reached in fog could be lowered by the aerosol number concentration, which could contribute to the sink term of water vapor during the radiative cooling. Although radiative fogs are usually associated with higher aerosol loading than stratus-lowering events, our analysis also reveals that the activated fraction at the beginning of the event is similar for both types of fog. However, the evolution of the droplet concentration during the fog life cycle shows significant differences between both types of fog. This work demonstrates that an accurate calculation of supersaturation is required to provide a realistic representation of fog microphysical properties in numerical models.

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Section: Instrumentationmentioning

confidence: 99%

Section: Instrumentationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Experimental study of the aerosol impact on fog microphysics

et al. 2019

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“…We note here that we have excluded the lowest (1-2 µm) bin of the cloud-droplet probe from our analysis to avoid potential noise issues with large, dry aerosol affecting the counts. Because of the low supersaturation and therefore high activation diameter, hydrated aerosol particles within fog can grow larger than micrometer in size and can contribute up to 68% of total light-scattering during different fog periods (Hammer et al, 2014;Elias et al, 2015). However, most of these hydrated particles are still too small to considerably affect interaction with long-10 wave radiation after fog has developed.…”

Section: Les Analysis 10mentioning

confidence: 99%

Aerosol-fog interaction and the transition to well-mixed radiation fog

Boutle¹,

Price²,

Kudzotsa³

et al. 2017

Preprint

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Abstract. We analyse the development of a radiation fog event and its gradual transition from optically thin fog in a stable boundary layer to well-mixed optically-thick fog. Comparison of observations and a detailed large-eddy simulation demonstrate that aerosol growth and activation is the key process in determining the onset of adiabatic fog. Weak turbulence and low supersaturations lead to the growth of aerosol particles which can significantly affect the visibility, but do not significantly interact with the long-wave radiation, allowing the atmosphere to remain stable. Only when a substantial fraction of the aerosol 5 become activated into cloud droplets can the fog interact with the radiation, becoming optically thick and well-mixed. Modifications to the parametrization of cloud droplet numbers in fog, resulting in lower and more realistic concentrations, are shown to give significant improvements to an NWP model, which initially struggled to accurately simulate the transition. Finally, consequences of this work for common aerosol activation parametrizations used in climate models are discussed, demonstrating that many schemes are reliant on an artificial minimum value when activating aerosol in fog, and adjustment of this minimum 10 can significantly affect the sensitivity of the climate system to aerosol radiative forcing.

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Fog trends in India: Relationships to fog type and western disturbances

Smith

Dorling

Renfrew

et al. 2022

Intl Journal of Climatology

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Fog is a major hazard in wintertime over India, particularly in the Indo-Gangetic Plains, leading to significant impacts for transport and human health. Using 3-hourly surface observations, from 69 sites across India, all fog and dense fog events between 2000 and 2020 are identified. For each event, the main fog formation mechanism is objectively categorized using a classification algorithm, distinguishing between radiation, advection, evaporation, precipitation or cloud-base lowering fog types. In contrast to the findings of other international studies, radiation fog dominates as the most common fog type at the vast majority of locations in India, accounting for 68.1% of all fog events and 70.0% of dense fog events. Statistically significant positive trends are seen in the frequency of all fog events at Delhi, Lucknow and Patna, in the Indo-Gangetic plains, between 1997/1998 and 2018/2019, dominated by comparable statistically significant positive trends in radiation fogs. Western disturbances (WD) are often linked to the formation of fog in India. Using a climatology of WDs, we show that 46.9% of radiation fog onsets in Delhi in December and January, the primary fog months, happened in conjunction with an active WD event. Conversely, only 32.3% of WDs during these same months coincided with the onset of a radiation fog event. WD-related radiation fog events are shown to cluster into three distinct groups, with WD centres located to the northwest (51.4% of cases), southwest (13.3%) and east (35.2%) of Delhi. Each cluster is shown to have coherent and distinct near-surface characteristics which are conducive to fog formation. Trends in WD frequency cannot fully account for the observed trends in fog events. We argue that the fog trends are more likely the result of a complex interaction between urban expansion and the associated rapid change in aerosol loading, resulting in impacts on radiation balance, microphysics and heat-island processes.

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Enhanced extinction of visible radiation due to hydrated aerosols in mist and fog

Cited by 24 publications

References 46 publications

Experimental study of the aerosol impact on fog microphysics

Experimental study of the aerosol impact on fog microphysics

Aerosol-fog interaction and the transition to well-mixed radiation fog

Fog trends in India: Relationships to fog type and western disturbances

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