Bright band: Difference between revisions

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Radar [[signature]] of the [[melting layer]]; a narrow horizontal layer of stronger [[radar reflectivity|radar  reflectivity]] in [[precipitation]] at the level in the [[atmosphere]] where [[snow]] melts to form [[rain]]. The  bright band is most readily observed on [[range&ndash;height indicator]] ([[RHI]]) or [[time&ndash;height indicator]]  ([[THI]]) displays.<br/> As [[ice crystals]] fall toward warmer temperatures at lower heights, they tend to aggregate and  form larger snowflakes. This growth accounts for an increase in radar reflectivity as the falling  [[particles]] approach the [[melting level]]. As they cross the 0&#x000b0;C level, the particles begin melting from  the surface inward and finally collapse into [[raindrops]]. The [[reflectivity]] maximum in the [[melting layer|melting  layer]] is explained partly by the difference in the value of the [[dielectric factor]], [[File:ams2001glos-Bex02.gif|link=|ams2001glos-Bex02]], of water and  [[ice]] (<br/>''see'' [[radar reflectivity]]). When a water film begins to form on a melting [[snowflake]], its radar  reflectivity may increase by as much as 6.5 dB because of the thermodynamic [[phase change]]. The  reflectivity decreases below the melting level because when flakes collapse into raindrops, their fall  velocities increase, causing a decrease in the number of precipitation particles per unit volume.  The size of the particles also becomes smaller in the melting process, as their [[density]] increases  from that of the snow and melting snow to that of liquid water. Both the reduction in size of the  precipitation particles and the decrease in their concentration lead to a decrease in the strength of  the [[radar echo]] at altitudes below the melting level, so that an isolated, horizontal layer of high  reflectivity is established, usually centered about 100 m below the 0&#x000b0;C [[isotherm]]. The bright band  is observed primarily in [[stratiform]] precipitation. The strong convective currents in active showers  and thunderstorms tend to destroy the horizontal [[stratification]] essential for creating and sustaining  the bright band.
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== bright band ==
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<div class="definition"><div class="short_definition">Radar [[signature]] of the [[melting layer]]; a narrow horizontal layer of stronger [[radar  reflectivity]] in [[precipitation]] at the level in the [[atmosphere]] where [[snow]] melts to form [[rain]]. The  bright band is most readily observed on [[range&ndash;height indicator]] ([[RHI]]) or [[time&ndash;height indicator]]  ([[THI]]) displays.</div><br/> <div class="paragraph">As [[ice crystals]] fall toward warmer temperatures at lower heights, they tend to aggregate and  form larger snowflakes. This growth accounts for an increase in radar reflectivity as the falling  [[particles]] approach the [[melting level]]. As they cross the 0&#x000b0;C level, the particles begin melting from  the surface inward and finally collapse into [[raindrops]]. The [[reflectivity]] maximum in the [[melting  layer]] is explained partly by the difference in the value of the [[dielectric factor]], <div class="inline-formula">[[File:ams2001glos-Bex02.gif|link=|ams2001glos-Bex02]]</div>, of water and  [[ice]] (<br/>''see'' [[radar reflectivity]]). When a water film begins to form on a melting [[snowflake]], its radar  reflectivity may increase by as much as 6.5 dB because of the thermodynamic [[phase change]]. The  reflectivity decreases below the melting level because when flakes collapse into raindrops, their fall  velocities increase, causing a decrease in the number of precipitation particles per unit volume.  The size of the particles also becomes smaller in the melting process, as their [[density]] increases  from that of the snow and melting snow to that of liquid water. Both the reduction in size of the  precipitation particles and the decrease in their concentration lead to a decrease in the strength of  the [[radar echo]] at altitudes below the melting level, so that an isolated, horizontal layer of high  reflectivity is established, usually centered about 100 m below the 0&#x000b0;C [[isotherm]]. The bright band  is observed primarily in [[stratiform]] precipitation. The strong convective currents in active showers  and thunderstorms tend to destroy the horizontal [[stratification]] essential for creating and sustaining  the bright band.</div><br/> </div>
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Latest revision as of 22:19, 13 January 2024

Radar signature of the melting layer; a narrow horizontal layer of stronger radar reflectivity in precipitation at the level in the atmosphere where snow melts to form rain. The bright band is most readily observed on range–height indicator (RHI) or time–height indicator (THI) displays.
As ice crystals fall toward warmer temperatures at lower heights, they tend to aggregate and form larger snowflakes. This growth accounts for an increase in radar reflectivity as the falling particles approach the melting level. As they cross the 0°C level, the particles begin melting from the surface inward and finally collapse into raindrops. The reflectivity maximum in the melting layer is explained partly by the difference in the value of the dielectric factor, ams2001glos-Bex02, of water and ice (
see radar reflectivity). When a water film begins to form on a melting snowflake, its radar reflectivity may increase by as much as 6.5 dB because of the thermodynamic phase change. The reflectivity decreases below the melting level because when flakes collapse into raindrops, their fall velocities increase, causing a decrease in the number of precipitation particles per unit volume. The size of the particles also becomes smaller in the melting process, as their density increases from that of the snow and melting snow to that of liquid water. Both the reduction in size of the precipitation particles and the decrease in their concentration lead to a decrease in the strength of the radar echo at altitudes below the melting level, so that an isolated, horizontal layer of high reflectivity is established, usually centered about 100 m below the 0°C isotherm. The bright band is observed primarily in stratiform precipitation. The strong convective currents in active showers and thunderstorms tend to destroy the horizontal stratification essential for creating and sustaining the bright band.


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