Effects of vernal equinox solar eclipse on temperature and wind direction in Switzerland

Eugster, Werner; Emmel, Carmen; Wolf, Sebastian; Buchmann, Nina; McFadden, J. P.; Whiteman, C. David

doi:10.5194/acp-17-14887-2017

Cited by 11 publications

(20 citation statements)

References 61 publications

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“…Similar near-surface thermal responses were also simulated by McInerney et al (2018). Second, the atmospheric pressure decreases due to the eclipse cyclone (Clayton, 1901;Eugster et al, 2017) in response to the rapid atmospheric cooling in the eclipse umbra. Pressure changes of 0.26-2.0 hPa have been observed (Anderson and Keefer, 1975;Aplin and Harrison, 2003;Eckermann et al, 2007;Aplin et al, 2016).…”

Section: Introductionmentioning

confidence: 52%

“…First, the near-surface air temperature decreases. The magnitude of this temperature change and timelag between the minimum solar radiation and the local minimum temperature is site-and event-dependent (e.g., on latitude, surface characteristics, synoptic forcing, cloud coverage, and time-of-day and duration of totality of the eclipse event), with an observed temperature drop of 1.5-10 • C (Stewart and Rouse, 1974;Anderson and Keefer, 1975;Aplin and Harrison, 2003;Aplin et al, 2016;Eugster et al, 2017), and with 15-20 min lags (Antonia et al, 1979;Aplin et al, 2016). Similar near-surface thermal responses were also simulated by McInerney et al (2018).…”

Section: Introductionmentioning

confidence: 99%

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Ensemble-Averaging Resolves Rapid Atmospheric Response to the 2017 Total Solar Eclipse

et al. 2019

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Rapid changes in solar radiative forcing influence heat, scalar and momentum fluxes and thereby shift the trajectory of near-surface atmospheric transitions. Surface fluxes are difficult to obtain during atmospheric transitions by either bulk or eddy-covariance methods because both techniques assume quasi-stationarity in an atmospheric state and require sufficiently long blocks of data, typically on the order of 10-30 min, to obtain statistically significant results. These computational requirements limit the temporal resolution of atmospheric processes that researchers can examine using traditional measurement techniques. In this paper, we present a novel observational approach to calculate surface fluxes at sub-minute temporal resolutions. High-frequency data from a horizontal, log-spaced array of nine time-synchronized ultrasonic anemometers were used to perform spatial-temporal ensemble averaging and to obtain eddycovariance turbulence fluxes at unprecedented time resolutions. The 2017 Great American Solar Eclipse event provided a "natural experiment" to test the ensembleobservation and averaging approach. A total eclipse is energetically well-constrained and, unlike day/night transitions, is a perturbation that quickly transitions from and back to a state of significant solar forcing, providing an ideal scenario for testing the space-timescales required for surface flux calculations. Additionally, two Doppler lidars and a vertically-oriented Distributed Temperature Sensing (DTS) system provided measurements to characterize near-surface atmospheric conditions. Results show that the ensemble-averaged sensible heat fluxes converged at timescales as short as 15 s. Additional analyses show that the timescale of the connection between the surface and the atmosphere is more rapid than previous measurements have been capable of showing and is on the order of 10 min or less. This experiment demonstrates that ensemble-flux measurements are capable of resolving fluctuations in surface fluxes during rapid atmospheric transitions.

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Section: Introductionmentioning

confidence: 52%

Section: Introductionmentioning

confidence: 99%

Ensemble-Averaging Resolves Rapid Atmospheric Response to the 2017 Total Solar Eclipse

et al. 2019

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“…We note that this average value is based on both partial and total solar eclipse events that occurred at various times throughout the day. Eugster et al [20] reported that the temperature reduction showed no dependence on eclipse type (partial vs. total), geographic location and several other factors. Additionally, the 5.0 • C recorded decrease is in line with other temperature measurements made across the continental United States by weather stations in the U.S.…”

Section: Radiosondesmentioning

confidence: 99%

“…A time lag between radiation changes and temperature response is visible in the main tower observations, with temperature decreasing following the decrease in radiation. The vertical temperature gradient at the main tower reversed at 14:06 EDT (35 min [20] compiled 130 historical observations of air temperature during solar eclipses dating back to 1834. The majority of these observations were taken within the paths of totality of total solar eclipses.…”

Section: Radiosondesmentioning

confidence: 99%

“…Anderson [19] suggested that rapid changes in thermally-driven orographic winds could be partially responsible for the anecdotal reports of the eclipse wind, a sudden increase in wind speed at totality. Eugster et al [20] used data from 165 surface weather stations in Switzerland to examine temperature and wind changes during the 20 March 2015 solar eclipse. Even though the eclipse was only partial in Switzerland, the cooling was sufficient to delay or prevent the morning transition to upvalley flows.…”

Section: Introductionmentioning

confidence: 99%

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Observations of Thermally-Driven Winds in a Small Valley during the 21 August 2017 Solar Eclipse

et al. 2019

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On the afternoon of 21 August 2017, a partial solar eclipse occurred over the Blue Ridge Mountains in central Virginia, USA. High-resolution meteorological observations were made on the floor of a small valley to investigate the effect of eclipse-induced cooling on thermally-driven winds. Measurements taken both at the surface and in the lower atmosphere indicate cooling throughout much of the atmospheric boundary layer. Multiple surface weather stations observed wind rotations that occurred both during and after the eclipse, as wind direction shifted from upvalley to downvalley and back to upvalley. The direction of these rotations (clockwise vs. counterclockwise) varied between stations and was strongly influenced by the proximity of the stations to topographic features in the valley. Doppler lidar observations over the valley floor show a 300 m thick layer of downvalley winds that formed below a deeper layer of upvalley winds. Changes in boundary layer winds and structure during the solar eclipse are similar to changes during the morning and evening transitions. However, the subtle differences in the direction of wind rotations between diurnal- and eclipse-transition periods provided important new insights into the interaction between slope- and valley flows, incoming solar radiation, and topographic features.

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The total solar eclipse of December 14, 2020 in southern South America and its effects on atmospheric variables

Piscitelli

Saurral

2021

Quart J Royal Meteoro Soc

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A total solar eclipse affected southern South America on December 14, 2020. Its occurrence close to the summer solstice in the Southern Hemisphere and around noon brought almost ideal conditions to study the effects of the sudden reduction in incoming solar radiation on different atmospheric variables. Interestingly, the astronomical phenomenon moved over a region that at that time was being affected by a cold front accompanied by significant cloudiness and cold air advection to the area. Therefore, the actual drop in surface temperature over the umbra region resulted from a combination of the radiative effect (i.e., the reduction in solar radiation due to the eclipse itself) and a circulation effect related to the injection of colder air. A quantification of both effects on the full temperature variation is provided, along with a discussion on the underlying mechanisms and the related effects on surface winds derived from the cooling.Results show that temperature drops associated with total solar eclipses in areas far away from the umbra can be as high as (or even higher than) those within the umbra, depending on the prevailing weather conditions.

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Effects of vernal equinox solar eclipse on temperature and wind direction in Switzerland

Cited by 11 publications

References 61 publications

Ensemble-Averaging Resolves Rapid Atmospheric Response to the 2017 Total Solar Eclipse

Ensemble-Averaging Resolves Rapid Atmospheric Response to the 2017 Total Solar Eclipse

Observations of Thermally-Driven Winds in a Small Valley during the 21 August 2017 Solar Eclipse

The total solar eclipse of December 14, 2020 in southern South America and its effects on atmospheric variables

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