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The three-dimensional structure of convective storms Robin Hogan John Nicol Robert Plant Peter Clark Kirsty Hanley Carol Halliwell Humphrey Lean Thorwald.

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Presentation on theme: "The three-dimensional structure of convective storms Robin Hogan John Nicol Robert Plant Peter Clark Kirsty Hanley Carol Halliwell Humphrey Lean Thorwald."— Presentation transcript:

1 The three-dimensional structure of convective storms Robin Hogan John Nicol Robert Plant Peter Clark Kirsty Hanley Carol Halliwell Humphrey Lean Thorwald Stein (t.h.m.stein@reading.ac.uk) www.met.reading.ac.uk/~dymecs (UK Met Office)

2 The three-dimensional structure of convective storms NWP models run at km-scale: errors in timing, location, structure of convective precipitation. Storm analysis of 2D fields (surface rainfall rate, OLR) highlights errors, but not underlying processes. Use high-resolution (300m) radar observations for many storms to evaluate model storm morphology and dynamics.

3 The three-dimensional structure of convective storms UKV 1500m 200m Animations by Robin Hogan

4 The DYMECS approach: beyond case studies Met Office 1km rainfall composite Track storms in real time and automatically scan Chilbolton radar Derive properties of hundreds of storms on ~40 days: Vertical velocity 3D structure Rain & hail Ice water content TKE & dissipation rate Evaluate these properties in model varying: Resolution Microphysics scheme Sub-grid turbulence parametrization 25m diameter S-band (3 GHz) Steerable (2 degrees per second) 0 dBZ out to 150 km

5 Storm structure from radar Distance east (km) Distance north (km) Radar reflectivity (dBZ) 40 dBZ 0 dBZ 20 dBZ

6 “Shallow” “Deep” ObservationsUKV 1500m200m Median storm diameter with height 500m “Convergence”? Lack of anvils? Drizzle from nowhere?

7 Vertical profiles of reflectivity 1.5-km 1.5-km + graupel 1.5-km no crystals Observations Conditioned on average reflectivity at 200-1000m below 0 o C. Reflectivity distributions for profiles with this mean Z 40-45 dBZ are shown. Model: High rainfall rate from storms lacking ice or have ice cloud dBZ<0 200-m

8 Model: For ice dBZ < 20 Top 50% of rain dBZ are 5-10 dB too high Interquartile range rain dBZ conditioned on ice dBZ No crystals? Aggregates-only rain dBZ 5-10 dB too low.

9 Updrafts? Hogan et al. (2008) –Track features in radial velocity from scan to scan Chapman & Browning (1998) –In quasi-2D features (e.g. squall lines) can assume continuity to estimate vertical velocity

10 Reflectivity Actual model vertical velocity Estimated vertical velocity ObservationsUKV 1500m Updraft retrieval 10 km height 20 km width 40 dBZ +10 m/s -10 m/s Estimate vertical velocity from vertical profiles of radial velocity, assuming zero divergence across plane. Quantify errors due to 2D flow assumption (slide courtesy John Nicol)

11 Observations500m Vertical velocity distributions with height updown up down 1. Derive map from PDF of estimates to PDF of true model velocities 2. Use map to simulate “true” observed PDF Radar data with dBZ>0 within 90 km of the radar Estimated vertical velocity True vertical velocity (slide courtesy John Nicol)

12 Vertical velocity distribution between 7-8 km True model velocity Estimated model velocity Radar estimated velocity Radar mapped “true” velocity map 500m simulation compares well with radar using 2D flow assumption (dashed lines) (slide courtesy John Nicol)

13 Evaluation of width of updrafts Model updrafts shrink with resolution –200-m model has about the right width –Does 100-m model shrink further or stay the same? –How does Smagorinsky mixing length affect model? Observations 200-m model 500-m model 1.5-km model Retrieval in both observations and model: w min =0.5 m/s; w max >3.0m/s True model versus mapped observations: w min =1.0 m/s; w max >5.0m/s

14 The three-dimensional structure of convective storms Thorwald Stein (t.h.m.stein@reading.ac.uk) www.met.reading.ac.uk/~dymecs Models with smaller grid length produce narrower storms, similar to observations. Models associate shallow ice cloud with high rainfall too frequently. 500m grid length model has vertical velocity distribution comparable to observations. Future work: Study the “E” of DYMECS.

15 Mixing-length sensitivity in 200m storm structures 100m mixing length 300m mixing length 40m mixing length 500m model1500m model 200m simulation can approximate storm structures in coarser grid- length simulations by varying mixing length

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