A41H-0154
10-Year Observations of Cloud and Surface Longwave Radiation at Ny-Ålesund, Svalbard

Thursday, 17 December 2015
Poster Hall (Moscone South)
Huidong Yeo1, Sang-Woo Kim1, Baek-Min Kim2, Joo-Hong Kim3, Masataka Shiobara4, Tae Jin Choi3, Seok-Woo Son1, Man-Hae Kim1, Jee-Hoon Jeong5 and Seong-Joong Kim2, (1)Seoul National University, Seoul, South Korea, (2)Korea Polar Research Institute, Incheon, South Korea, (3)KOPRI Korea Polar Research Institute, Incheon, South Korea, (4)NIPR National Institute of Polar Research, Tokyo, Japan, (5)Chonnam national university, Gwangju, South Korea
Abstract:
Arctic clouds play a key role in surface radiation budget and may influence sea ice and snow melting. In this study, 10-year (2004-2013) observations of cloud from Micro-Pulse Lidar (MPL) and surface longwave (LW) radiation at Ny-Ålesund, Svalbard are analyzed to investigate cloud radiative effect. The cloud fraction (CF) derived from MPL shows distinct monthly variation, having higher CF (0.90) in summer and lower CF (0.79) in winter. Downward longwave radiation (DLW) during wintertime (Nov., Dec., Jan., and Feb.) decreases as cloud base height (CBH) increases. The DLW for CBH < 1km (264.7±35.4 W m-2) is approximately 1.46 times larger than that for cloud-free (181.8±25.8 W m-2) conditions. The temperature difference (ΔT) and DLW difference (ΔDLW), which are calculated as the difference of monthly mean temperature and DLW between all-sky and cloud-free conditions, are positively correlated (R2 = 0.83). This implies that an increase of DLW may influence surface warming, which can result in snow and sea ice melting. However, dramatic changes in surface temperature, cloud and DLW are observed with a time scale of a few days. The averaged surface temperature on the presence of low-level clouds (CBH < 2km) and under cloud-free conditions are estimated to be -6.9±6.1°C and -14.5±5.7°C, respectively. The duration of low-level clouds, showing relatively high DLW and high surface temperature, is about 2.5 days. This suggests that DLW induced by low-level clouds may not have a critical effect on surface temperature rising and sea ice melting.