Canadian In Situ Snow Cover Trends for 1955–2017 Including an Assessment of the Impact of Automation

IF 1.6 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmosphere-Ocean Pub Date : 2021-03-15 DOI:10.1080/07055900.2021.1911781

R. Brown, C. Smith, C. Derksen, L. Mudryk

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引用次数: 13

Abstract

ABSTRACT Snow cover trends for Canada over the 1955–2017 period for the daily snow depth–observing network of Environment and Climate Change Canada (ECCC) are presented based on an updated quality-controlled historical daily in situ snow depth dataset. The period since approximately 1995 is characterized by a rapid decline in manual observations (loss of over 800 manual observing sites between 1995 and 2017) and an increasing number of automated stations equipped with sonic snow depth sensors. In 2017 these accounted for approximately 45% of the network and more than 80% of the snow depth–observing network north of latitude 55°N. Automated stations are characterized by more frequent missing and anomalous data than manual ruler observations, particularly at Arctic sites. A comparison of closely located automated sonic and manual ruler observations showed similar numbers of days with snow cover but the sonic sensors detected significantly lower snow depths. For time series analysis of annual snow cover variables, the systematic difference between ruler and sonic snow depth can be removed using a common 2003–2016 reference period to compute snow cover anomalies. The updated trend results are broadly similar to previously published assessments showing long-term decreases in annual snow cover duration (SCD) and snow depth over most of Canada, with the largest decreases observed in spring snow cover and seasonal maximum snow depth (SDmax). Significant declines in SCD and SDmax of −1.7 (±1.1) days decade-1 and −1.8 cm (±0.8) cm decade−1 were observed in the Canada–averaged series over the 1955–2017 period. These trends mainly reflect snow cover conditions over southern Canada where the observing network is concentrated and where there are significant negative correlations between snow cover and winter air temperature. Declining numbers of stations reporting snow depth, issues with sonic sensor data quality, and systematic differences between ruler and sonic sensor measurements are major challenges for continued climate monitoring with the current ECCC snow depth–observing network.

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1955年至2017年加拿大现场积雪趋势，包括自动化影响评估

摘要加拿大环境与气候变化观测网络（ECCC）1955年至2017年期间加拿大的积雪趋势基于更新的质量控制历史每日现场积雪深度数据集。大约自1995年以来，人工观测的特点是快速下降（1995年至2017年间，失去了800多个人工观测点），配备声波雪深传感器的自动化站数量不断增加。2017年，它们约占网络的45%，占北纬55°以北雪深观测网络的80%以上。与手动标尺观测相比，自动观测站的特点是数据丢失和异常更频繁，尤其是在北极地区。对位置较近的自动声波和手动标尺观测结果的比较显示，积雪天数相似，但声波传感器检测到的雪深明显较低。对于年度积雪变量的时间序列分析，可以使用通用的2003-2016参考期来计算积雪异常，从而消除标尺和声波积雪深度之间的系统差异。更新后的趋势结果与之前公布的评估大致相似，显示加拿大大部分地区的年积雪持续时间（SCD）和积雪深度长期下降，春季积雪和季节性最大积雪深度（SDmax）下降幅度最大。SCD和SDmax在十年-1和-1.8的−1.7（±1.1）天内显著下降 1955年至2017年期间，在加拿大平均序列中观察到cm（±0.8）cm decade−1。这些趋势主要反映了加拿大南部的积雪情况，那里的观测网络很集中，积雪与冬季气温之间存在显著的负相关性。报告雪深的台站数量下降、声波传感器数据质量问题以及标尺和声波传感器测量之间的系统差异，是当前ECCC雪深观测网络持续进行气候监测的主要挑战。

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来源期刊

Atmosphere-Ocean 地学-海洋学

CiteScore

2.50

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： Atmosphere-Ocean is the principal scientific journal of the Canadian Meteorological and Oceanographic Society (CMOS). It contains results of original research, survey articles, notes and comments on published papers in all fields of the atmospheric, oceanographic and hydrological sciences. Arctic, coastal and mid- to high-latitude regions are areas of particular interest. Applied or fundamental research contributions in English or French on the following topics are welcomed: climate and climatology; observation technology, remote sensing; forecasting, modelling, numerical methods; physics, dynamics, chemistry, biogeochemistry; boundary layers, pollution, aerosols; circulation, cloud physics, hydrology, air-sea interactions; waves, ice, energy exchange and related environmental topics.