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(Top) 1 Formula 2 Critical values and interpretation 3 See also 4 References 5 Further reading

Bulk Richardson number

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The Bulk Richardson Number (BRN) is an approximation of the Gradient Richardson number.^[1] The BRN is a dimensionless ratio in meteorology related to the consumption of turbulence divided by the shear production (the generation of turbulence kinetic energy caused by wind shear) of turbulence. It is used to show dynamic stability and the formation of turbulence.

The BRN is used frequently in meteorology due to widely available rawinsonde|Radiosonde|rawinsonde (frequently called radiosonde) data and numerical weather forecasts that supply wind and temperature measurements at discrete points in space.^[2]

Formula[edit]

Below is the formula for the BRN. Where g is gravitational acceleration, T_v is absolute virtual temperature, Δθ_v is the virtual potential temperature difference across a layer of thickness Δz (vertical depth), and ΔU and ΔV are the changes in horizontal wind components across that same layer.^[1]

R_{B}={\frac {(g/T_{v})\Delta \theta _{v}\Delta z}{(\Delta U)^{2}+(\Delta V)^{2}}}

Critical values and interpretation[edit]

High values indicate unstable and/or weakly-sheared environments; low values indicate weak instability and/or strong vertical shear. Generally, values in the range of around 10 to 50 suggest environmental conditions favorable for supercell development.^[3]

In the limit of layer thickness becoming small, the Bulk Richardson number approaches the Gradient Richardson number, for which a critical Richardson number is roughly Ri_c= 0.25. Numbers less than this critical value are dynamically unstable and likely to become or remain turbulent.^[1]

The critical value of 0.25 applies only for local gradients, not for finite differences across thick layers. The thicker the layer is the more likely we are to average out large gradients that occur within small sub-regions of the layer of interest. This results in uncertainty of our prediction of the occurrence of turbulence, and now one must use an artificially large value of the critical Richardson number to give reasonable results using our smoothed gradients. This means that the thinner the layer, the closer the value to the theory.^[2]

References[edit]

^ ^a ^b ^c "Bulk richardson number". AMS Glossary. American Meteorological Society. Retrieved 2015-12-29.

^ ^a ^b Stull, Roland (31 July 1988). An Introduction to Boundary Layer Meteorology. Norwell, MA: Kluwer Academic Publishers. pp. 177–180. ISBN 978-90-277-2769-5.

^ "Glossary". NOAA National Weather Service. Retrieved 2015-12-29.

Further reading[edit]

Help - Bulk Richardson Number - NOAA Storm Prediction Center
Thompson, Richard L.; Edwards, Roger; Hart, John A.; Elmore, Kimberly L.; Markowski, Paul (December 2003). "Close Proximity Soundings within Supercell Environments Obtained from the Rapid Update Cycle" (PDF). Weather and Forecasting. 18 (6). American Meteorological Society: 1243–1261. Bibcode:2003WtFor..18.1243T. doi:10.1175/1520-0434(2003)018<1243:CPSWSE>2.0.CO;2.

v t e Meteorological data and variables
General	Adiabatic processes Advection Buoyancy Lapse rate Lightning Surface solar radiation Surface weather analysis Visibility Vorticity Wind Wind shear
Condensation	Cloud Cloud condensation nuclei (CCN) Fog Convective condensation level (CCL) Lifted condensation level (LCL) Precipitable water Precipitation Water vapor
Convection	Convective available potential energy (CAPE) Convective inhibition (CIN) Convective instability Convective momentum transport Conditional symmetric instability Convective temperature (T_c) Equilibrium level (EL) Free convective layer (FCL) Helicity K Index Level of free convection (LFC) Lifted index (LI) Maximum parcel level (MPL) Bulk Richardson number (BRN)
Temperature	Dew point (T_d) Dew point depression Dry-bulb temperature Equivalent temperature (T_e) Forest fire weather index Haines Index Heat index Humidex Humidity Relative humidity (RH) Mixing ratio Potential temperature (θ) Equivalent potential temperature (θ_e) Sea surface temperature (SST) Temperature anomaly Thermodynamic temperature Vapor pressure Virtual temperature Wet-bulb temperature Wet-bulb globe temperature Wet-bulb potential temperature Wind chill
Pressure	Atmospheric pressure Baroclinity Barotropicity Pressure gradient Pressure-gradient force (PGF)
Velocity	Maximum potential intensity

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