Simulated Increase of Hurricane Intensities in a CO2-Warmed Climate

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Presentation transcript:

Simulated Increase of Hurricane Intensities in a CO2-Warmed Climate by Thomas R. Knutson, Robert E. Tuleya, and Yoshio Kurihara Science Volume 279(5353):1018-1021 February 13, 1998 ©1998 by American Association for the Advancement of Science

Figure 1 Geographical distribution of the maximum surface wind speeds (in meters per second) observed during 1971–1992 (A) and simulated (B and C) for tropical storms in the northwest Pacific basin. Geographical distribution of the maximum surface wind speeds (in meters per second) observed during 1971–1992 (A) and simulated (B and C) for tropical storms in the northwest Pacific basin. Observations are from the Joint Typhoon Warning Center (Guam) as compiled by C. J. Neumann in 1993, available from the National Center for Atmospheric Research athttp://www.scd.ucar.edu/dss (ds824.1). The simulated distributions are based on 71 case studies each under control (B) and high-CO2 (C) conditions; results from 20 preliminary cases under each condition (9) were included in order to increase spatial coverage. Blank (white) regions denote areas where no tropical storms were reported during 1971–1992 (A) or none occurred in the case studies [(B) and (C)]. Thomas R. Knutson et al. Science 1998;279:1018-1021 ©1998 by American Association for the Advancement of Science

Figure 2 Frequency distribution of maximum surface wind speeds obtained from the hurricane model in 51 case studies each from control (dashed line) and high-CO2 (solid line) conditions. Frequency distribution of maximum surface wind speeds obtained from the hurricane model in 51 case studies each from control (dashed line) and high-CO2 (solid line) conditions. Thomas R. Knutson et al. Science 1998;279:1018-1021 ©1998 by American Association for the Advancement of Science

Figure 3 Scatter plot of minimum surface pressure versus local SST obtained from the hurricane model in 51 case studies each under control (circles) and high-CO2 (asterisks) conditions. Scatter plot of minimum surface pressure versus local SST obtained from the hurricane model in 51 case studies each under control (circles) and high-CO2 (asterisks) conditions. The dark curve is drawn to schematically illustrate an expanding envelope of attainable surface pressures with increasing SST. The dashed line indicates the 860-mb level discussed in the text. Thomas R. Knutson et al. Science 1998;279:1018-1021 ©1998 by American Association for the Advancement of Science

Figure 4 (A) Dark lines show the fifth strongest storm intensity for each hour under control (dashed) or high-CO2 (solid) conditions; shading depicts 95% confidence intervals for control conditions. (A) Dark lines show the fifth strongest storm intensity for each hour under control (dashed) or high-CO2 (solid) conditions; shading depicts 95% confidence intervals for control conditions. Small circles (one to three rows) indicate periods when the high-CO2 distribution is significantly lower than the control distribution at the 0.1, 0.05, or 0.01 levels, respectively, according to a KS test. (B) Central surface pressure for control (dark dashed line) and high-CO2 (dark solid line) idealized experiments. Difference curves [light solid lines in (A) and (B)] are offset by +830 mb. Thomas R. Knutson et al. Science 1998;279:1018-1021 ©1998 by American Association for the Advancement of Science