Eight-year measurements at urban (Xujiahui, XJH) and remote (Dongtan, DT) stations during 2010-2017 are employed to examine the surface ozone (O₃)-temperature relationship in Shanghai, China. O₃ pollution was getting worse in Shanghai, with daily maximum O₃ concentrations increasing at a rate of 2.45 ppb yr^-1 in urban site. The climate penalty (m_O3-T), defined as the slope of O₃ change with increasing temperature, exhibited largest values in summer. Summertime O₃ increased faster as temperature increased, with mean rates of 6.7 and 13.7 ppb °C^-1, respectively in XJH and DT above 30°C. Sensitivity experiments indicate that the temperature dependence of biogenic volatile organic compounds (VOCs) emissions should be the main chemical driver of the high-temperature O₃ response in summer, since simulated values of m_O3-T are most sensitive to the temperature-related changes in biogenic isoprene emissions. NO_x emission reductions strengthened the high-temperature O₃ response in Shanghai, with summer mean m_O3-T values increasing from 1.52 ppb°C^-1 during 2010-2012 to 2.97 ppb °C^-1 during 2013-2017. As NO_x emissions continue to decrease, the dependence of m_O3-T on the biogenic VOC emissions could be weakened. Model results suggest that reductions in anthropogenic VOC emission reductions would effectively reduce the sensitively of O₃ to increasing temperatures in urban Shanghai. Effective emission reduction strategies should be formulated to balance VOC/NO_x ratios, so as to wrestle with the challenges for future O₃ pollution.