Publications

Du, QJ; Yi, GH; Zhou, XB; Zhang, TB; Li, JJ; Xie, HJ; Hu, J (2021). Analysis of asymmetry in diurnal warming and its impact on vegetation phenology in the Qinghai-Tibetan Plateau using MODIS remote sensing data. JOURNAL OF APPLIED REMOTE SENSING, 15(2), 28502.

Abstract
Because of its high altitude, the Qinghai-Tibetan Plateau (QTP) serves as a de facto ecological barrier between China and Southeast Asia. Studying the phenological characteristics of vegetation on QTP and their response to climate change can help us to understand how climate change can impact on highland terrestrial ecosystems and how to improve predicting highland vegetation phenology. Using long-term NDVI data we derived from the MODIS spectral reflectance product (MOD09A1) and in situ climate data in QTP, we investigated (1) the trends of temporal and spatial variations in the phenological characteristics of the highland vegetation, such as the start of growing season (SOS), middle time of growing season (MOS), end of growing season (EOS), and length of growing season (LEN), and (2) the responses of SOS, MOS, and EOS to asymmetry in diurnal warming, i.e., asymmetry in the preseason daily daytime maximum temperature (T-max) and daily nighttime minimum temperature (T-min). Results showed that (1) the vegetation phenology in QTP displayed a salient zonal distribution pattern. From the northwest to the southeast, the vegetation SOS and MOS gradually advanced, EOS decreased, and LEN extended; (2) T-min warmed up faster than T-max, which indicated that daytime warming and nighttime warming were asymmetrical; (3) the increase in preseason T-max and that in preseason T-min played different roles in SOS, MOS, and EOS; and (4) the preseason T-min showed a stronger control on vegetation phenology than the preseason T-max. For instance, a 1 degrees C increase in preseason T-min advanced SOS by 7.07d (p < 0.05) and MOS by 6.80d (p < 0.05), and delayed EOS by 6.70d (p < 0.05). While a 1 degrees C increase in preseason T-max delayed the SOS, MOS, and EOS by 5.12d, 4.84d, and 1.04d, respectively. (C) 2021 Society of Photo-Optical Instrumentation Engineers (SPIE)

DOI:
10.1117/1.JRS.15.028502

ISSN:
1931-3195