Abstract
The relationship between sea-level pressure (SLP) and 1,000 hPa air temperature (AT) in winter is investigated over the northern hemisphere, and a statistical forecasting of one of the two parameters from the other is attempted on a monthly basis. Mean monthly SLP and 1,000 hPa level AT values at 563 grid points over the northern hemisphere are utilized for January, February and March, for the period 1949–2002. At first, factor analysis is applied to the data sets as a dimensionality reduction tool. Then, canonical correlation analysis is applied to the resultant factor scores time series for the five SLP–AT pairs: SLP(J)–AT(J), SLP(J)–AT(F), SLP(J)–AT(M), AT(J)–SLP(F) and AT(J)–SLP(M), and the synchronous and time-lag connections between the two parameters are investigated. The areas characterized by a satisfactory monthly or/and bi-monthly forecasting ability are detected. The most satisfactory results refer to the areas affected by the Southern Oscillation. It is found that the SLP teleconnection between the areas of the eastern and the western Pacific in January is related to the regime of AT in the central Pacific Ocean, in both February and March. Also, SLP over the Aleutian and Icelandic lows in January is related to AT over their southwestern and southeastern neighbouring areas in February and March. Finally, it appears that there is also ability for monthly/bi-monthly statistical prediction for some areas affected by the well-known oscillations of North Atlantic Oscillation and Pacific/North American Oscillation. A validation of the statistical prediction methodology is carried out, using real-time series of AT and SLP parameters for some characteristic cases. The results show that the statistical prediction presents a remarkable success. The success rate varies from 67% to 83% for the analysis period 1949–2002 and from 71% to 86% for the recent period 2003–2009.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Allan R, Lindesay J, Parker D (1996) El Nino Southern Oscillation and climate variability. CSIRO, Australia
Anderson JH, van den Doll HM et al (1997) Capabilities of dynamical and statistical methods for atmospheric extra-tropical seasonal prediction. In: Proceedings of the Twenty-Second Annual Climate Diagnostics and Prediction Workshop, October 6–10, 1997, Berkeley US Department of Commerce, NOAA, NWS, CPC/NCEP, pp 46–49
Anderson DLT, Stockdale T, Balmaseda MA, Ferranti L, Vitart F, Doblas-Reyas P, Hagedorn R, Jung T, Vidard A, Troccoli A, Palmer T (2003) Comparison of the ECMWF seasonal forecast systems 1 and 2, including the relative performance for the 1997/8 El Niño. Technical Memoranda 404, ECMWF, Shinfield Park, Reading, UK
Barnett T, Preisendorfer R (1987) Origins and levels of monthly and seasonal forecasts skill for the United States surface air temperatures determined by canonical correlation analysis. Mon Weather Rev 115:1825–1850
Bartzokas A, Metaxas DA (1993) Covariability and climatic changes of the lower-troposphere temperatures over the northern hemisphere. Il Nuovo Cimento 16C:359–373
Bartzokas A, Metaxas DA, Giles BD (2002) On the relation between sea surface and lower troposphere temperature over the northern hemisphere. GLOBAL NEST. Int J 4:127–137
Bartzokas A, Lolis CJ, Metaxas DA (2003) The 850 hPa relative vorticity centres of action for winter precipitation in the Greek area. Int J Climatol 23:813–828
Bretherton CS, Smith S, Wallace J (1992) An intercomparison of methods for finding coupled patterns in climate data. J Clim 5:541–560
Casey TM (1995) Optimal linear combination of seasonal forecasts. Aust Meteorol Mag 44:219–224
Cassou C, Terray L, Hurrell J, Deser C (2004) North Atlantic winter climate regimes: spatial asymmetry, stationarity with time, and oceanic forcing. J Clim 17:1055–1068
Cassou C, Deser C, Alexander MA (2007) Investigating the impact of remerging sea surface temperature anomalies on the winter atmospheric circulation over the North Atlantic. J Clim 20(14):3510–3526
Chu PS, Katz RW, Ding P (1995) Modeling and forecasting seasonal precipitation in Florida—a vector time-domain approach. Int J Climatol 15:53–64
Corte-Real J, Zhang X, Wang X (1995) Large-scale circulation regimes and surface climatic anomalies over the Mediterranean. Int J Climatol 15:1135–1150
Diaz AF, Studzinski CD, Mechoso CR (1998) Relationships between precipitation anomalies in Uruguay and southern Brazil and sea surface temperature in the Pacific and Atlantic oceans. J Clim 11:251–271
Elfandy MG, Ashour ZH, Taiel SMM (1994) Time-series models adoptable for forecasting Nile floods and Ethiopian rainfalls. J Clim 12:1974–1989
Glantz MH, Nicholls N, Katz RW (1991) Teleconnections linking worldwide anomalies. Cambridge University Press, Cambridge
Goddard L, Mason SJ, Zebiak SE, Ropelewski CF, Basher R, Cane MA (2001) Current approaches to seasonal-to-interannual climate predictions. Int J Climatol 21:1111–1152
Graham RJ, Gordon M, McLean PJ, Ineson S, Huddleston MR, Davey MK, Brookshaw A, Barnes RTH (2005) A performance comparison of coupled and uncoupled versions of the Met Office seasonal prediction general circulation model. Tellus A 57(3):320–339
Hilmer M, Jung T (2000) Evidence for a recent change in the link between the North Atlantic Oscillation and Arctic sea ice export. Geophys Res Lett 27:989–992
Horel JD (1981) A rotated principal component analysis of the interannual variability of the northern hemisphere 500 mPa height field. Mon Weather Rev 109:2080–2092
Jin EK, Kinter JL III, Wang B, Authors C (2008) Current status of ENSO prediction skill in coupled ocean–atmosphere model. Clim Dyn 31:647–666. doi:10.1007/s00382008-0397-3
Johnson N, Feldstein C, Tremblay B (2008) The continuum of northern hemisphere teleconnection patterns and a description of the NAO shift with the use of self-organizing maps. J Clim 21(23):6354
Jolliffe IT (1986) Principal component analysis. Springer, New York
Jung T, Hilmer M, Ruprecht E, Kleppek S (2003) Characteristics of the recent eastward shift of interannual NAO variability. J Clim 16:3371–3382
Kalnay E, Kanamitsu M, Kistler R, Collins W, Deaven D, Gandin L, Iredell M, Saha S, White G, Woollen J, Zhu Y, Leetmaa A, Reynolds B, Chelliah M, Ebisuzaki W, Higgins W, Janowiak J, Mo KC, Ropelewski C, Wang J, Jenne R, Joseph D (1996) The NCEP/NCAR 40-year reanalysis project. Bull Am Meteorol Soc 77:437–471
Kiladis GN, Diaz HF (1989) Global climatic anomalies associated with extremes in the Southern Oscillation. J Clim 12:1854–1992
Kirtmam BP (2003) The COLA anomaly coupled model: ensemble ENSO prediction. Mon Weather Rev 131:2324–2341
Kistler R, Kalnay E, Collins W, Saha S, White G, Woollen J, Chelliah M, Ebisuzaki W, Kanamitsu M, Kousky V, van den Dool H, Jenne R, Fiorino M (2001) The NCEP/NCAR 50-year reanalysis: monthly means CD-ROM and documentation. Bull Am Meteorol Soc 82:247–267
Kushnir Y (2002) Pacific North America pattern. In: Encyclopedia of global environmental change. Wiley, Chichester
Lamb PJ, Peppler RA (1987) North Atlantic oscillation: concept and an application. Bull Am Meteorol Soc 68:1218–1225
Landman WA, Mason SJ (2001) Forecasts of near-global sea-surface temperatures using canonical correlation analysis. J Clim 14:3819–3833
Lehmiller GS, Kimberlain TB, Elsner JB (1997) Seasonal prediction models for North Atlantic basin hurricane location. Mon Weather Rev 125:1780–1791
Lolis CJ, Bartzokas A (2001) Winter temperature covariances in the middle and the lower troposphere over Europe and the North Atlantic Ocean. Int J Climatol 21:679–696
Luo D, Gong T (2006) A possible mechanism for the eastward shift of interannual NAO action centers in last three decades. Geophys Res Lett 33:L24815. doi:10.1029/2006GL027860
Manly BFJ (1986) Multivariate statistical methods: a primer. Chapman & Hall, London, p 159
Mason SJ, Goddard L (2001) Probabilistic precipitation anomalies associated with ENSO. Bull Am Meteorol Soc 82:619–638
Mason SJ, Mimmack GM (2002) Comparison of some statistical methods of probabilistic forecasting of ENSO. J Clim 15:8–29
Mason SJ, Goddard L, Graham NE, Yulaeva E, Sun L, Arkin PA (1999) The IRI seasonal climate prediction system and the 1997/1998 El Nino event. Bull Am Meteorol Soc 80:1853–1873
Mentz RP, D’Urso MA, Jarma NM, Mentz GB (2000) Cyclical components of local rainfall data. Int J Climatol 20:211–228
Navarra A, Ward MN, Rayner NA (1998) A stochastic model of SST for climate simulation experiments. Clim Dyn 14:473–487
Nicholls N, Katz RW (1991) Teleconnections and their implications for long-range forecasts. In: Glantz MH (ed) Teleconnections linking worldwide climate anomalies. Cambridge University Press, New York
Overland JE, Preisendorfer RW (1982) A significant test for principal components applied to cyclone climatology. Mon Wea Rev 110:1–4
Penland C, Matrovosa L (1998) Prediction of tropical Atlantic sea surface temperatures using linear inverse modelling. J Clim 11:483–496
Peterson KA, Lu J, Greatbatch RJ (2003) Evidence of nonlinear dynamics in the eastward shift of the NAO. Geophys Res Lett 30:1030. doi:10.1029/2002GL015585
Pezzi LP, Repelli CR, Nobre P, Cavalcanti IFA, Sampaio G (1998) Forecasts of tropical Atlantic SST using a statistical ocean model at CPTEC/INPE—Brazil. Exp Long-Lead Forecast Bull 7(1):28–31
Philander SG (1983) El Niño Southern Oscillation phenomena. Nature 302:295–301
Quiring SM, Blair D (2000) The utility of global teleconnections for long-range crop forecasting in the Canadian prairies. In: Romanowski J (ed) Prairie perspectives: geographical essays, vol 3. University of Manitoba, Winnipeg, pp 23–61
Rasmusson EM, Carpenter TH (1982) Variations in tropical sea surface temperature and surface wind fields associated with the Southern Oscillation/El Niño. Mon Weather Rev 110:354–384
Rasmusson EM, Wallace JM (1983) Meteorological aspects of the El Ninõ/Southern Oscillation. Science 222:1195–1202
Repelli CA, Nobre P (2004) Statistical prediction of sea surface temperature over the tropical Atlantic. Int J Climatol 24:45–55
Richman MB (1986) Rotation of principal components. J Climatol 6:293–335
Rogers JC (1990) Patterns of low-frequency monthly sea level pressure variability (1899–1986) and associated wave cyclone frequencies. J Clim 3:1364–1379
Sharma S (1995) Applied multivariate techniques. Wiley, New York
Sheridan SC (2003) North American weather-type frequency and teleconnection indices. Int J Climatol 23:27–45
Solomon A, Jin FF (2005) A study of the impact of off-equatorial warm pool SST anomalies on ENSO cycles. J Clim 18(2):274–286
Sutton RT, Allen MR (1997) Decadal predictability of North Atlantic sea surface temperature and climate. Nature 388:563–567
Trenberth KE (1991) General characteristics of El Niño–Southern Oscillation. In: Glantz MH, Katz RW, Nicholls N (eds) Teleconnections linking worldwide climate anomalies: scientific basis and societal impact. Cambridge University Press, Cambridge, pp 13–42
Trenberth KE, Hoar TJ (1996) The 1990–1995 El Niño—Southern Oscillation event: longest on record. Geophys Res Lett 23:57–60
Trenberth KE, Hurrell JW (1999) Comments on “The interpretation of short climate records with comments on the North Atlantic and Southern Oscillations”. Bull Amer Meteor Soc 80:2721–2722
Ulbrich U, Christoph M (1999) A shift of the NAO and increasing storm track activity over Europe due to anthropogenic greenhouse gas forcing. Clim Dyn 15:551–559
Uppenbrink J (1997) Seasonal climate prediction. Science 277:1952
Van den Dool HM (1994) Long-range weather forecasts through numerical and empirical methods. Dyn Atmos Oceans 20(3):247–270
van Loon H, Madden RA (1981) The Southern Oscillation. Part I: global associations with pressure and temperature in northern winter. Mon Wea Rev 109:1150–1162
van Loon H, Rogers JC (1978) The seesaw in winter temperatures between Greenland and Northern Europe. Part I: general description. Mon Weather Rev 106:296–310
Wallace JM, Gutzler DS (1981) Teleconnections in the geopotential height field during the northern hemisphere winter. Mon Weather Rev 109:784–812
Wallace JM, Thompson DWJ (2000) Northern hemisphere teleconnection patterns during extreme phases of the zonal mean circulation. J Clim 13(5):1037–1039
Wanner H, Brönnimann S, Casty C, Gyalistras D, Luterbacher J, Schmutz C, Stephenson DB, Xoplaki E (2001) North Atlantic Oscillation—concepts and studies. Surv Geophys 22:321–382
Ward NM, Folland CK (1991) Prediction of seasonal rainfall in the north Nordeste of Brazil using eigenvectors of sea-surface temperatures. Int J Climatol 11:711–743
Xoplaki E, Luterbacher J, Burkard B, Patrikas I, Maheras P (2000) Connection between the large-scale 500 hPa geopotential height fields and precipitation over Greece during wintertime. Clim Res 14:129–146
Zorita E, Viacheslav K, Von Storch H (1992) The atmospheric circulation and sea surface temperature in the North Atlantic area in winter: their interaction and relevance for Iberian precipitation. J Clim 5:1097–1108
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Papadimas, C.D., Bartzokas, A., Lolis, C.J. et al. Sea-level pressure–air temperature teleconnections during northern hemisphere winter. Theor Appl Climatol 108, 173–189 (2012). https://doi.org/10.1007/s00704-011-0523-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00704-011-0523-8