The Implication of Ural Blocking on the East Asian Winter Climate in CMIP5 Models

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The Implication of Ural Blocking on the East Asian Winter Climate in CMIP5 Models Hoffman H. N. Cheung, Wen Zhou (hncheung-c@my.cityu.edu.hk) City University of Hong Kong Shenzhen Institute Guy Carpenter Asia-Pacific Climate Impact Centre, School of Energy and Environment, City University of Hong Kong Conference on East Asia and Western Pacific Meteorology and Climate 2-4 Nov 2013, Hong Kong SAR 1

Why Ural blocking? Jan 2008 NH Blocking freq in Jan Ural-Siberia -1950-2007 -2008 --- 95-th percentile Atlantic Pacific Fig 1. (Top) A schematic diagram showing the blocking pattern in Jan 2008, (Bottom) Longitudinal distribution of blocking frequency [From Zhou et al. 2009 MWR]. 2

IPCC AR5 WG1 report, Ch. 14 Questions When compared to observational reanalysis, 1. How well do CMIP5 models reproduce the wintertime Ural blocking (UB) and its associated circulation pattern? 2. To what extent are CMIP5 models able to capture the relationship between UB and the EAWM? 3. What are the implications of UB on the East Asian winter climate? 3

Data 25 winters (DJF), 1980/81-2004/05 25 CMIP5 models vs. NCEP-NCAR reanalysis (OBS) Multiple model ensemble (MME): Unweighted average of 25 CMIP5 models Table 1. List of 25 CMIP5 models. Acron ym Institution, Country Model Horizontal resolution (lat x lon) 144x192 AC1 ACCESS1-0 CSIRO, Australia AC2 ACCESS1-3 144x192 BC1 BCC-CSM1-1 64x128 BCC, China BC2 BCC-CSM1-1(m) 160x320 CAN CCCma, Canada CanESM2 64x128 CM1 CMCC-CESM 48x96 CM2 CMCC, Italy CMCC-CM 240x480 CM3 CMCC-CMS 96x192 CNR CNRM, France CNRM-CM5 128x256 FGO IAP-LASG, China FGOALS-g2 60x128 GF1 GFDL-CM3 90x144 GF2 GFDL, USA GFDL-ESM2G 90x144 GF3 GFDL-ESM2M 90x144 Horizontal Acron Institution, Model resolution ym Country (lat x lon) HAD MOHC, UK HadGEM2-CC 144x192 IP1 IPSL-CM5A-LR 96x96 IP2 IPSL, France IPSL-CM5A-MR 143x144 IP3 IPSL-CM5B-LR 96x96 MI1 MIROC5 128x256 MI2 MIROC-ESM 64x128 CCSR, Japan MI3 MIROC-ESM- 64x128 CHEM MP1 MPI-ESM-LR 96x192 MP2 MPI-M, Germany MPI-ESM-MR 96x192 MP3 MPI-ESM-P 96x192 MRI MRI, Japan MRI-CGCM3 160x320 NOR NCC, Norway NorESM1-M 96x144 4

Climatology of atmospheric blocking Reversal of north-south geopotential height gradients over the mid-latitudes (Tibaldi and Molteni 1990 Tellus) Applying zonal index equations, ZGN λ Z λ,ϕ Z λ,ϕ ϕ ϕ 10 gpm deg lat ZGS λ,, 0 Z500 λ,ϕ Z500 λ,ϕ 0 where λ 0,357.5 E ϕ 80 N, ϕ 60 N, ϕ 40 N, 5, 2.5,0,2.5 or 5 Minimum extension: 12.5 degrees Minimum persistence: 4 days Fig 2. The 25-year wintertime blocking frequency climatology in the Northern Hemisphere. 5

Developing stage (day -2 wrt UB onset) Z500 anomaly MSLP anomaly Compared to OBS, Upstream: The low Z500 anomaly over Europe shifts southeastward; Center: The high anomaly over the Urals: slightly shifts eastward; gpm hpa Downstream The low Z500 anomaly near Japan is very pronounced in the MME but not robust across the CMIP5 models. Fig 3. Composite maps of the Z500 anomaly (contour, unit: gpm) and the MSLP anomaly (shading, unit: hpa) on day -2 with respect to the UB onset. 6

Mature stage (day 0, UB onset) Z500 anomaly MSLP anomaly Compared to day -2, Upstream: Like day -2, the low anomaly over Europe shifts southeastward; Surface low anomaly weakens; Center: The high anomaly extends eastward toward western Siberia; Downstream The low anomaly over western Siberia becomes robust, corresponding to intensification of the surface Siberian high. Fig 4. Composite maps of the Z500 anomaly (contour, unit: gpm) and the MSLP anomaly (shading, unit: hpa) on the UB onset date. 7

Mature stage (day 2 wrt UB onset) Z500 anomaly MSLP anomaly Compared to day 0, Upstream: The low anomaly further weakens and no coherent signals can be seen; Center: The blocking high persists; Downstream The low Z500 anomaly over western Siberia is still robust; The Siberian high extends southeastward toward East Asia; Fig 5. Composite maps of the Z500 anomaly (contour, unit: gpm) and the MSLP anomaly (shading, unit: hpa) on day 2 with respect to the UB onset. 8

Siberian high intensity during the evolution of UB Fig 6. Time series showing the daily Siberian high index (SHI; MSLP anomaly over 40 o -65 o N, 80 o -120 o E). 9

Cause and effect of bias of Ural blocking Z500 b) MSLP Ural blocking index (UBI) Blocking frequency over 45 o -90 o E UBI bias UBI of a CMIP5 model minus UBI of OBS Fig 7. Linkage between the long-term mean bias of the UBI and that of the winter-mean circulation in the 25 CMIP5 models. UBI bias across the models is related to mean circulation bias over the Atlantic region (a +ve NAO-like dipole pattern). UBI bias seems not significantly impact the East Asian winter-mean circulation. 10

Relationship between UB and large-scale circulation Z500 MSLP Fig 8. (top) Regression of Ural blocking index (UBI) against the Z500 and MSLP in the MME; (bottom) coherence of the regression coefficients across the CMIP5 models. 11

Relationship between long-term mean of Ural blocking frequency and Siberian high intensity 10% significance Fig 9. Linear correlation coefficient between the Ural blocking index (UBI) and the Siberian high index (SHI) as a function of the UBI in the 25 CMIP5 models. 12

Relationship between long-term variance of Ural blocking frequency and Siberian high intensity Fig 10. Year-to-year variance of Siberian high index (SHI) as a function of the year-toyear variance of Ural blocking index (UBI) in the 25 CMIP5 models during the period 1980/81-2004/05. 13

Hypotheses UB events usually persists for less than two weeks Wintertime UB frequency accounts for significant fraction of long-term variance of the Siberian high (~30%) UB rarely exerts a persistent forcing on the East Asian winter monsoon (EAWM) Models have different ability of simulating UB frequency Performance of UB simulation unlikely affects the mean state of the EAWM Performance of UB simulation probably affects the longterm variance of the EAWM 14

Summary Most of CMIP5 models are able to simulate the large-scale circulation features associated with Ural blocking, though the center of action over the Atlantic has a southeastward shift compared to OBS; 1) Low height anomaly over the North Atlantic Ocean H 3) A trough over the Asian continent L 2) A ridge/blocking high over the European continent or the Urals L The bias of Ural blocking in CMIP5 models is attributed to the mean circulation bias over the Euro-Atlantic region, which may affect the storm activities. Among the CMIP5 models, the long-term variance bias of Ural blocking may contribute to the that of Siberian high intensity, so does the EAWM circulation. Ural blocking is important for assessing the variability of the EAWM. 15

Outlook of future climate conditions Period: 2075/76-2099/2100 Fig 11. Change of blocking frequency in the RCP4.5 and RCP8.5 scenario compared to the historical scenario of CMIP5 GCMs. No systematic change of blocking frequency in the Ural sector. 16

Outlook of future climate conditions RCP 4.5 RCP 8.5 Fig 12. Linkage between the long-term mean bias of the UBI and that of the winter-mean circulation in the future climate condition of CMIP5 models. 17

Thank you! All comments are appreciated! 18

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