Le Kuai 1 , Runlie Shia 1 , Xun Jiang 2 , Ka-Kit Tung 3 , Yuk L. Yung 1

1. Does the Solar Cycle Increase or Decrease the Period of the Quasi-Biennial Oscillation? A Modeling Study Le Kuai1, Runlie Shia1, Xun Jiang2, Ka-Kit Tung3, Yuk L. Yung1

2. Previous work • Pascoe, et al. (2005), Salby and Callaghan (2000): westerly period of the equatorial QBO longer during the solar min • Soukhrarew and Hood’s (2001): both phases of QBO periods were longer during SC-min. • Fisher, and K.K. Tung (2007) that the anti-correlation of QBO period with the solar cycle mentioned by Salby and Calleghan breaks down in the solar min of 1997 with QBO period as low as about 25 months when there were no major volcanic perturbations.

3. Advantage of model • Provide longer time period • (82 yr, more than 6 solar cycle) • Without volcanic influence in the simulation • Provide the solar radiation perpetual condition

4. The run with five-time solar-max perpetual condition The run with solar-min perpetual condition • Total QBO period is lengthened • Both phase durations are increased • Westerly descent rate < 1 month delayed; Easterly descent rate ~ 5 months longer

5. FFT analysis of equatorial zonal wind at 30 hPa QBO period: 5xSC-max > 1xSC-max > 1xSC-min

6. Increasing trend due to enlarged solar radiationAbove 30 hPa:Easterly > Westerly Below 30 hPa:Westerly > Easterly • NCEP: E-QBO/W-QBO gradually decrease/increase from 10 hPa ~ 50 hPa • Model: Constant at upper three levels • Both see the stalling at 50 hPa W-QBO longer than E-QBO • The stalling is strengthened by solar radiation

7. More sudden warming events during solar max years Slow down the critical line descent rate Brewer Dobson circulation stronger in solar-max condition Upwelling at equatorial lower stratosphere More downdraft at polar region

8. Conclusions: • A positive correlation between the lengthen of QBO period and the solar cycle flux • Each phase duration is extended. Stronger elongation in E-QBO above 30 hPa but in W-QBO below this level. • Easterly phase stalling is stronger during larger solar radiation.

9. Thank you & Question?

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