Past and projected future changes of North Atlantic polar low frequency
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Past and projected future changes of North Atlantic polar low frequency Matthias Zahn ESSC-University of Reading currently working with Richard Allan and Lennart Bengtsson he PREPARE project Based on my PhD work at GKSS research centre and University of Hamburg Supervised by Hans von Storch and Stephan Bakan 2 Intro Investigation of long-term changes • Long-term dataset of polar low cases • Comprehensive measurements required • long in time • high in spatial detail • homogeneous • Problem: Such measurements do usually no exist 3 Intro Solution Use of a numerical model (Regional Climate Model, RCM) in combination with existing global data to reconstruct past/ project future state of the atmosphere: “dynamical downscaling“ Global data (~200 km) RCM (~50 km) Intro Setup of my work Part 1: Polar lows in RCMs Part 2: Detect polar lows automatically Part 3: Compilation of past polar low climatology in addition to my PhD work: Part 4: Projection of future polar low activity 4 P1 Ensemble simulations for three polar low cases in climate mode NCEP (~200 km) CLM (~50 km) Oct. 1993 (Dec. 1993, Jan. 1998) Initialised: approx. 2 week prior to PL formation With spectral Nudging (4x) and without (4x) (v. Storch et al. 2000) 5 P1 Mean Sea level pressure (hPa) and 10m wind speed 15. Oct. 1993, 6:00 Dundee 15.10.93, 05:24 NCEP DWD 6 P1 Mean Sea level pressure (hPa) and 10m wind speed 15. Oct. 1993, 6:00 NCEP DWD Dundee 15.10.93, 05:24 CLM01nn CLM02nn CLM03nn CLM04nn CLM01sn CLM02sn CLM03sn CLM04sn 7 P1 8 Bandpass filtered mslp (hPa) 15 Oct. 1993, 6:00 NCEP DWD Scales between 200-600 km are retained CLM01nn CLM02nn CLM03nn CLM04nn CLM01sn CLM02sn CLM03sn CLM04sn P1 9 Dec 1993 case 9 Dec 1993, 0:00 Greenland Iceland NCEP CLM22-nn Dundee Weatherchart, DWD CLM22-sn 9.12.93, 16:00 CLM22-sn, filtered 10 Jan 1998 case 18 Jan 1998, 0:00 Berliner NCEP Weatherchart Dundee 18.1.98, 4:00 Sc an din av ia P1 CLM01-nn CLM01-sn CLM01-sn, filtered P1 11 Results from case studies • In principle, polar lows can be reproduced with CLM run in climate mode • Deviations in detail (e.g. location and amount of pressure minima) • Spectral nudging inhibits considerable ensemble variability • A digital bandpass filter could be useful for an automatic detection Zahn et al, 2008, Tellus P2 12 Setup of the detection algorithm st 1 : detection of minima in the filtered mslp fields (< -1hPa) 2nd : combine detected positions to individual tracks, distance to next (3h) pos < ~200 km 3rd : checking further constraints along the tracks: • strength of the minimum ( ≤ −2hPa once along the track) • wind speed ( ≥ 13.9 m/s once along the track) • air-sea temperature difference ( SST − T 500hPa ≥ 43K) • north south direction of the track • limits to allowable adjacent grid boxes OR: strength of the minimum in the bandpass filtered mslp field decreases below −6hPa once Zahn and v. Storch, 2008a, MetZeit P3 13 Set-up of long-term simulation: NCEP/NCAR reanalysis 1/ CLM 2.4.6 Initialised: 1.1.1948 finishing: 28.2.2006 spectral nudging of scales > 700 km P3 14 Tracks of three Polar Lows Reproduced and detected even after a simulation time of 40 years 15 Frequency of polar lows Zahn and v.Storch, 2008b, GRL PLS: Polar Low Season (Jul-Jun) P3 P3 16 Frequency of polar lows Zahn and v.Storch, 2008b, GRL Mean:56 Min:36 Max:100 σ=13 P3 17 Number of polar lows per PLS Zahn and v.Storch (2008b) (black) and observations (red) of Wilhelmsen (1985) Zahn and v.Storch (2008b) (black) and observations (red) of MetNo (Noer, pers comm) Similar courses of polar low frequency PLS: Polar Low Season (Jul-Jun) 18 P3 C=0,58 C=0,72 Monthly comparison of Zahn and v.Storch (2008b) (in black) with observed data (in red) u.r.: Norwegian Met. Service l.l.: Blechschmidt (2008) P3 19 Density of polar low genesis Similar spatial characteristics Bracegirdle, T. J. and S. L. Gray, 2008 P3 20 Hindcast results Strong inter annual variability Frequency remains on a similar level Qualitative similarity with observations/ other studies Zahn and v.Storch, 2008b, GRL P4 Polar lows in IPCC-climate change scenarios Global data delivered by IPCC-AR4-ECHAM5-MPI-OM experiments: C20: Control with GHG 1960-1990 - B1,A1B,A2: projected for period 2070-2100 21 P4 22 Number of polar lows per PLS Zahn and v.Storch, 2010, Nature P4 23 Evolution of SST and T500 Measure of vertical stability: vdT = SST - T500 Zahn and v.Storch, 2012, in AGU GM 24 P4 Projected changes in polar low frequency and vertical atmospheric stability C20 B1 A1B A2 Zahn and v.Storch, 2010, Nature P4 Spatial density distribution, northward shift of genesis region C20, mean lat = 64,9° N B1, mean lat = 66,8° N A1B, mean lat = 66,8° N A2, mean lat = 67,3° N 25 P4 26 Final Results Hindcasts: Strong inter annual variability Frequency remained on a similar level In climate warming scenarios: Polar lows become less frequent Their mean origin regions shift farther north Atmosphere becomes more stable P5 Thanks a lot for your attention Homepage: http://www.nerc-essc.ac.uk/~maz/ 27 P5 28 Outlook ● Myself: Post-Doc (supervised by Richard Allan and Lennart Bengtsson) on hydrological cycle: PREPARE project: Projected Response of Extreme Precipitation and Atmospheric Radiative Energy P1 29 2-d digital bandpass filter Digital bandpassfilters are able to separate large, medium and small scales in gridded RCM output fields (Feser and v. Storch, Example from DWD 15. 10. 1993, 6:00 am 30 Intro intense/ strong winds (>13.9 m/s) severe weather typically induced by disturbances in the air flow ~300 km Sca n occur poleward the Polar Fronts in both hemispheres during winter din mesoscale (< 1000 km) sized maritime storms avia S pi t ber zge n Polar lows (mesoscale cyclones) typically driven by convective processes © Dundee Satellite Receiving Station
