- Example of freezing rain, Canada
- Example of freezing rain, SE Europe
- Example of freezing rain, France
- Example of freezing drizzle, SE England
Example of freezing rain, Canada
Freezing rain is a very hazardous type of precipitation which brings a significant risk to aviation, transport, communication and indeed to life. There are outputs to highlight the probability and amounts of freezing rain. An indication of freezing precipitation gives no information on likely accumulation of glazed ice although there must be a serious risk. Heavier precipitation rates suggest a potential for greater accumulation.
Fig8.1.10-10A: HRES forecasts freezing rain (total over 12hr). DT 00UTC 23 February 2018, T+72 VT 00UTC 26 February 2018. Colour scale: Light Blue 0.0-0.2mm, Mid Blue 0.2-0.5mm, Dark Blue 0.5-1.0mm, Dark Red 1.0-2.0mm, Red 2.0-5.0mm, Pink 5.0-10.0mm, Orange >10.0mm. The pin marks the location of Quebec City with the forecast 12hr total of freezing rain given in the probe information frame. Freezing rain total values are not the same as accumulation of glaze or glazed ice although some proportional accretion must be expected.
Fig8.1.10-10B: The ensemble forecasts freezing rain probability (>1mm over 12hr). DT 00UTC 23 February 2018, T+72 VT 00UTC 26 February 2018. Colour scale: Yellow 5-35%, Green 35-65%, Darker Green 65-95%, Blue >95%. The pin marks the location of Quebec City with the forecast probability of >1mm 12hr total of freezing rain given in the probe information frame.
Fig:8.1.10-11: ecCharts presentation of HRES forecast freezing rain accumulations over the previous 6hr, DT 00UTC 16 February 2023, T+42 VT 18UTC 17 February 2023. The vertical profile at Bangor, Maine, USA shows the classic freezing rain structure of a very moist and precipitating frontal zone overlying the sub-zero layer near the surface.
Example of freezing rain, SE Europe
Northward advection of warm moist air over Ukraine and above an undercut of very cold air from southern Russia and the North Caucasus region is depicted on charts as an upper warm front. Vertical profiles at Kyiv and Odesa show the typical structure of the cold and warm airmasses. Freezing rain at the surface occurs where the precipitating warm saturated air falls into the underlying cold relatively dry air. The structure of the atmosphere at the intersection of the air masses is typified by the vertical profile at Kryve Ozero. The precipitation area extended from Kyiv in the north to the Black Sea in the south. Ice pellets were forecast on the northern flank of the freezing rain where the temperature in the warm air only just exceeded zero deg C. Significant hazard may be expected where high extreme forecast precipitation indices intersect areas where freezing rain is forecast.
Fig:8.1.10-15: Forecast of freezing rain over Ukraine VT 06UTC 08 January 2024, DT 00UTC 06 January 2024. Colours show 6hr totals of freezing rain. Arrows show 10m winds. 2m isotherms in red. Vertical profile and type of precipitation histogram for Odesa, in the warm air.
Fig:8.1.10-16: Forecast of freezing rain over Ukraine VT 06UTC 08 January 2024, DT 00UTC 06 January 2024. Colours show 6hr totals of freezing rain. Arrows show 10m winds. 2m isotherms in red. Vertical profile and type of precipitation histogram for Kryve Ozero, in the area of freezing rain. The vertical profile shows temperatures above 0°C in a layer about 1000m thick.
Fig:8.1.10-17: Forecast of freezing rain over Ukraine VT 06UTC 08 January 2024, DT 00UTC 06 January 2024. Colours show 6hr totals of freezing rain. Arrows show 10m winds. 2m isotherms in red. Vertical profile and type of precipitation histogram for Kyiv, in the cold air.
Fig:8.1.10-18: Forecast of freezing rain over Ukraine VT 06UTC 08 January 2024, DT 00UTC 06 January 2024. Colours show 6hr totals of freezing rain. Coloured spots show type of precipitation. Vertical profile and type of precipitation for a location near Uman, on the northern flank of the area of freezing rain. The vertical profile shows temperatures just above 0°C in a thin layer. Orange spots show ice pellets.
Fig:8.1.10-19: Forecast of freezing rain over Ukraine VT 06UTC 08 January 2024, DT 00UTC 06 January 2024. Blue/purple colours show 6hr totals of freezing rain. Red/orange colours show precipitation extreme forecast index for precipitation. Arrows show 10m winds. 2m isotherms in red. Insets show EFI and CDF for 24hr precipitation for point with pin west of Odesa.
Fig:8.1.10-20: Surface analysis from Met Office VT12UTC 08 January 2024. The area of freezing rain is shown as an upper warm front.
Example of freezing rain, France
An intensifying slow-moving frontal zone was slow-moving across northern France and southern Germany. The front separated very cold air to the north from warm moist air to the south. Precipitation type histograms from a series of ensemble forecasts consistently identified the risk of freezing rain. The structure of the forecast atmosphere at the intersection of the air masses is typified by the vertical profile at Paris. Ice pellets were forecast at Bonn on the northern flank of the freezing rain where the temperature in the warm air only just exceeded zero deg C.
Fig:8.1.10-21: Precipitation type histograms for Paris from a series of ensemble forecasts.
Fig:8.1.10-22: Precipitation type histograms for Paris from a series of ensemble forecasts.
Fig:8.1.10-23: Forecast vertical profile at Paris to the north of the surface front with typical zone of positive temperatures above an undercutting sub-zero cold zone. The vertical profiles compare the forecast profile (red) and observed profile (black). The forecast vertical profile captured the underlying cold dry air and overlying warm air quite well.
Fig:8.1.10-24: Forecast vertical profile at Idar-Oberstein to the north of the frontal zone with typical zone of positive temperatures above an undercutting sub-zero cold zone. The vertical profiles compare the forecast profile (red) and observed profile (black). The forecast vertical profile didn't capture the observed structure completely. It wasn't cold enough in the lowest layers (observed surface temperature -4°C but forecast 2m temperature -1°C) and the layer with temperatures above 0°C was forecast to be too deep. Nevertheless the forecast temperature structure was sufficient for the HRES to produce freezing rain and ice pellets.
Example of freezing drizzle, SE England
Freezing drizzle can be as much of a hazard as freezing rain. The "Probability of Freezing Rain" option on ecCharts can show 0% when the default threshold is used. Freezing drizzle can be seen if a very low threshold (say >0.01mm in previous 6hr) is applied.
Fig:8.1.10-14 ecCharts presentation of ensemble forecast of probability of freezing rain accumulations, threshold 0.01 mm in previous 6 hr, DT 12UTC 24 January 2023, T+21 VT 09UTC 25 January 2023. The vertical profile at Reading (located by the pin) shows a saturated layer of stratus at about 950 hPa with temperature above 0°C. Very slight precipitation produced from the stratus by the model falls through an underlying sub-zero layer near the surface. The model gave above 65% probability of very light freezing precipitation. Freezing drizzle was observed at Reading during the period.
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