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Warming spring air temperatures, but delayed spring streamflow in an Arctic headwater basin

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Warming spring air temperatures, but delayed spring streamflow in an Arctic headwater basin. / Shi, Xiaogang; Marsh, Philip; Yang, Daqing.
In: Environmental Research Letters, Vol. 10, No. 6, 064003, 01.06.2015.

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Shi X, Marsh P, Yang D. Warming spring air temperatures, but delayed spring streamflow in an Arctic headwater basin. Environmental Research Letters. 2015 Jun 1;10(6):064003. doi: 10.1088/1748-9326/10/6/064003

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Shi, Xiaogang ; Marsh, Philip ; Yang, Daqing. / Warming spring air temperatures, but delayed spring streamflow in an Arctic headwater basin. In: Environmental Research Letters. 2015 ; Vol. 10, No. 6.

Bibtex

@article{4fa6dd4e7ab645a186e4a5564601fd9f,
title = "Warming spring air temperatures, but delayed spring streamflow in an Arctic headwater basin",
abstract = "This study will use the Mann-Kendall (MK) non-parametric trend test to examine timing changes in spring (early May to the end of June) streamflow records observed by the Water Survey of Canada during 1985-2011 in an Arctic headwater basin in the Western Canadian Arctic. The MK test shows a general delay in the five timing measures of springtime streamflow, which are based on the 5 percentile (Q5), 10 percentile (Q10), 50 percentile (Q50), 90 percentile (Q90), and 95 percentile (Q95) dates of spring runoff, respectively. However, much stronger trend signals were clearly noted for the high percentiles than that for the low and middle percentiles, indicating different effects of hydroclimate processes working on the timing of springtime streamflow. In contrast, the earlier snowmelt onset derived from daily mean temperatures was found over the 27-year study period. In addition, multiple relationships were correlated between these five timing measures of spring runoff and five hydroclimate indicators (total snowfall, snowmelt onset, spring temperature fluctuation, spring rainfall, and spring rainfall timing) in order to identify possible causes on the changes of springtime streamflow timing. The results indicate that the differences are due to the contradictory effects of winter-spring air temperature changes, temperature fluctuation during the melting period, and spring rainfall to spring runoff. The earlier snowmelt onset, which is attributed to the winter-spring warming, and spring temperature fluctuation that works in the opposite way, result in the minor timing changes of Q5, Q10, and Q50. The increase in spring rainfall and its delayed timing have a significant impact on the dates of Q90 and Q95. Moreover, the decreased total snow accumulation over the winter season only has a minor influence on the timing of springtime streamflow.",
keywords = "rainfall, snowfall, snowmelt onset, streamflow, temperature fluctuation, timing, warming",
author = "Xiaogang Shi and Philip Marsh and Daqing Yang",
year = "2015",
month = jun,
day = "1",
doi = "10.1088/1748-9326/10/6/064003",
language = "English",
volume = "10",
journal = "Environmental Research Letters",
issn = "1748-9318",
publisher = "IOP Publishing Ltd",
number = "6",

}

RIS

TY - JOUR

T1 - Warming spring air temperatures, but delayed spring streamflow in an Arctic headwater basin

AU - Shi, Xiaogang

AU - Marsh, Philip

AU - Yang, Daqing

PY - 2015/6/1

Y1 - 2015/6/1

N2 - This study will use the Mann-Kendall (MK) non-parametric trend test to examine timing changes in spring (early May to the end of June) streamflow records observed by the Water Survey of Canada during 1985-2011 in an Arctic headwater basin in the Western Canadian Arctic. The MK test shows a general delay in the five timing measures of springtime streamflow, which are based on the 5 percentile (Q5), 10 percentile (Q10), 50 percentile (Q50), 90 percentile (Q90), and 95 percentile (Q95) dates of spring runoff, respectively. However, much stronger trend signals were clearly noted for the high percentiles than that for the low and middle percentiles, indicating different effects of hydroclimate processes working on the timing of springtime streamflow. In contrast, the earlier snowmelt onset derived from daily mean temperatures was found over the 27-year study period. In addition, multiple relationships were correlated between these five timing measures of spring runoff and five hydroclimate indicators (total snowfall, snowmelt onset, spring temperature fluctuation, spring rainfall, and spring rainfall timing) in order to identify possible causes on the changes of springtime streamflow timing. The results indicate that the differences are due to the contradictory effects of winter-spring air temperature changes, temperature fluctuation during the melting period, and spring rainfall to spring runoff. The earlier snowmelt onset, which is attributed to the winter-spring warming, and spring temperature fluctuation that works in the opposite way, result in the minor timing changes of Q5, Q10, and Q50. The increase in spring rainfall and its delayed timing have a significant impact on the dates of Q90 and Q95. Moreover, the decreased total snow accumulation over the winter season only has a minor influence on the timing of springtime streamflow.

AB - This study will use the Mann-Kendall (MK) non-parametric trend test to examine timing changes in spring (early May to the end of June) streamflow records observed by the Water Survey of Canada during 1985-2011 in an Arctic headwater basin in the Western Canadian Arctic. The MK test shows a general delay in the five timing measures of springtime streamflow, which are based on the 5 percentile (Q5), 10 percentile (Q10), 50 percentile (Q50), 90 percentile (Q90), and 95 percentile (Q95) dates of spring runoff, respectively. However, much stronger trend signals were clearly noted for the high percentiles than that for the low and middle percentiles, indicating different effects of hydroclimate processes working on the timing of springtime streamflow. In contrast, the earlier snowmelt onset derived from daily mean temperatures was found over the 27-year study period. In addition, multiple relationships were correlated between these five timing measures of spring runoff and five hydroclimate indicators (total snowfall, snowmelt onset, spring temperature fluctuation, spring rainfall, and spring rainfall timing) in order to identify possible causes on the changes of springtime streamflow timing. The results indicate that the differences are due to the contradictory effects of winter-spring air temperature changes, temperature fluctuation during the melting period, and spring rainfall to spring runoff. The earlier snowmelt onset, which is attributed to the winter-spring warming, and spring temperature fluctuation that works in the opposite way, result in the minor timing changes of Q5, Q10, and Q50. The increase in spring rainfall and its delayed timing have a significant impact on the dates of Q90 and Q95. Moreover, the decreased total snow accumulation over the winter season only has a minor influence on the timing of springtime streamflow.

KW - rainfall

KW - snowfall

KW - snowmelt onset

KW - streamflow

KW - temperature fluctuation

KW - timing

KW - warming

U2 - 10.1088/1748-9326/10/6/064003

DO - 10.1088/1748-9326/10/6/064003

M3 - Journal article

AN - SCOPUS:84937484926

VL - 10

JO - Environmental Research Letters

JF - Environmental Research Letters

SN - 1748-9318

IS - 6

M1 - 064003

ER -