[1]QIANG Haofan,JIN Xiaoyan,ZHAO Lu,et al.Dry-Wet Condition Variations in Zoige Wetland in Recent 56 Years Based on Relative Humidity Index[J].Research of Soil and Water Conservation,2018,25(01):172-177,182.
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Dry-Wet Condition Variations in Zoige Wetland in Recent 56 Years Based on Relative Humidity Index
Research of Soil and Water Conservation[ISSN 1005-3409/CN 61-1272/P] Volume:
25
Number of periods:
2018 01
Page number:
172-177,182
Column:
Public date:
2018-02-28
- Title:
- Dry-Wet Condition Variations in Zoige Wetland in Recent 56 Years Based on Relative Humidity Index
- Keywords:
- Zoige Wetland; relative humidity index; Mann-Kendall method; wavelet analysis; season variations
- CLC:
- P462.2
- DOI:
- -
- Abstract:
- Based on the daily meteorological data from 5 stations in Zoige Wetland, the relative humidity index was calculated. Mann-Kendall method and Morlet wavelet analysis were used to analyze the changes of dry-wet conditions and meteorological elements in recent 56 years. The Pearson correlation coefficient method was used to study the cause of relative humidity index variations. The results showed that:(1) the annual relative humidity index of Zoige Wetland was significantly decreasing (p < 0.05) with the tendency of -0.018/decade, showing the significantly dry trend, it was relative arid in winter and spring with the trend towards humidification, while summer and autumn were humid relatively with the trend towards acidification in recent 56 years, the drought was most serious in winter, followed by spring, year, summer and autumn; (2) there was the significant abrupt point of autumn towards acidification in 1995 (p < 0.05) while no mutant phenomena were found in other time scales; (3) periodic oscillation with multiple times scales of annual and seasonal relative humidity index existed with the oscillation circulation of 25~30 years, 12~15 years and 7~10 years, and winter may still be dry in future short-term; (4) the decrease of precipitation and relative humidity, increase of sunshine duration and potential evapotranspiration played the major role in wetland drying tendency, while the effect of average temperature and wind speed increase was minor. Precipitation was the dominant factor on the dry-wet condition variations of wetland.
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