Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River

The Stillaguamish River in northwest Washington State is an important regional water resource for local agriculture, industry, and First Nations tribes and a critical habitat for several threatened and endangered salmonid species, including the Chinook salmon. The river is currently subject to a tem...

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Bibliographic Details
Main Author: Clarke, Katherine Mary
Format: Text
Language:English
Published: Western CEDAR 2020
Subjects:
climate change
hydrology
modeling
streamflow
stream temperature
Stillaguamish River
salmon habitat
DHSVM
RBM
Geology
South Fork
First Nations
Online Access:https://cedar.wwu.edu/wwuet/983
https://cedar.wwu.edu/context/wwuet/article/2008/viewcontent/Clarke_Thesis_Final.pdf
id ftwestwashington:oai:cedar.wwu.edu:wwuet-2008
record_format openpolar
spelling ftwestwashington:oai:cedar.wwu.edu:wwuet-2008 2023-06-11T04:11:45+02:00 Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River Clarke, Katherine Mary 2020-01-01T08:00:00Z application/pdf https://cedar.wwu.edu/wwuet/983 https://cedar.wwu.edu/context/wwuet/article/2008/viewcontent/Clarke_Thesis_Final.pdf English eng Western CEDAR https://cedar.wwu.edu/wwuet/983 https://cedar.wwu.edu/context/wwuet/article/2008/viewcontent/Clarke_Thesis_Final.pdf Copying of this document in whole or in part is allowable only for scholarly purposes. It is understood, however, that any copying or publication of this document for commercial purposes, or for financial gain, shall not be allowed without the author’s written permission. WWU Graduate School Collection climate change hydrology modeling streamflow stream temperature Stillaguamish River salmon habitat DHSVM RBM Geology text 2020 ftwestwashington 2023-05-07T16:43:04Z The Stillaguamish River in northwest Washington State is an important regional water resource for local agriculture, industry, and First Nations tribes and a critical habitat for several threatened and endangered salmonid species, including the Chinook salmon. The river is currently subject to a temperature total maximum daily load, so it is important to understand how projected climate change will affect future stream temperatures and thus salmon populations. Snowpack is the main contributor to spring and summer streamflow and helps to mitigate stream temperatures as air temperatures rise through the summer in the South Fork of the Stillaguamish River. I used gridded historical meteorological data to calibrate the physically-based Distributed Hydrology Soil Vegetation Model and River Basin Model and then applied downscaled, gridded projected climate data to predict how a changing climate will influence hydrology and stream temperature in the South Fork basin through the end of the 21st century. My projected modeling results predict that increasing air temperatures will cause the South Fork basin to shift from a snow-dominated basin to a rain-dominated basin through the 21st century. This will result in up to a 60% increase in winter streamflow and a 50% decrease in basin-wide snowpack. Snowpack will begin to melt out earlier in the year, resulting in an average 58% decrease in spring and summer streamflow and increased stream temperatures. Average monthly stream temperatures could increase by as much as 6.4 ºC by the 2075 climate normal. The largest increases in stream temperatures occur in the spring due to a reduction in snowmelt. The warmest stream temperatures occur in July due to reduced streamflows and warmer air temperatures. Washington State Department of Ecology stream temperature thresholds for salmonid habitat are already being exceeding each year and will be increasingly exceeded through the end of the century. Projected increased stream temperatures will cause additional stress to already ... Text First Nations Western Washington University: CEDAR (Contributing to Education through Digital Access to Research) South Fork ENVELOPE(161.250,161.250,-77.567,-77.567)
institution Open Polar
collection Western Washington University: CEDAR (Contributing to Education through Digital Access to Research)
op_collection_id ftwestwashington
language English
topic climate change
hydrology
modeling
streamflow
stream temperature
Stillaguamish River
salmon habitat
DHSVM
RBM
Geology
spellingShingle climate change
hydrology
modeling
streamflow
stream temperature
Stillaguamish River
salmon habitat
DHSVM
RBM
Geology
Clarke, Katherine Mary
Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River
topic_facet climate change
hydrology
modeling
streamflow
stream temperature
Stillaguamish River
salmon habitat
DHSVM
RBM
Geology
description The Stillaguamish River in northwest Washington State is an important regional water resource for local agriculture, industry, and First Nations tribes and a critical habitat for several threatened and endangered salmonid species, including the Chinook salmon. The river is currently subject to a temperature total maximum daily load, so it is important to understand how projected climate change will affect future stream temperatures and thus salmon populations. Snowpack is the main contributor to spring and summer streamflow and helps to mitigate stream temperatures as air temperatures rise through the summer in the South Fork of the Stillaguamish River. I used gridded historical meteorological data to calibrate the physically-based Distributed Hydrology Soil Vegetation Model and River Basin Model and then applied downscaled, gridded projected climate data to predict how a changing climate will influence hydrology and stream temperature in the South Fork basin through the end of the 21st century. My projected modeling results predict that increasing air temperatures will cause the South Fork basin to shift from a snow-dominated basin to a rain-dominated basin through the 21st century. This will result in up to a 60% increase in winter streamflow and a 50% decrease in basin-wide snowpack. Snowpack will begin to melt out earlier in the year, resulting in an average 58% decrease in spring and summer streamflow and increased stream temperatures. Average monthly stream temperatures could increase by as much as 6.4 ºC by the 2075 climate normal. The largest increases in stream temperatures occur in the spring due to a reduction in snowmelt. The warmest stream temperatures occur in July due to reduced streamflows and warmer air temperatures. Washington State Department of Ecology stream temperature thresholds for salmonid habitat are already being exceeding each year and will be increasingly exceeded through the end of the century. Projected increased stream temperatures will cause additional stress to already ...
format Text
author Clarke, Katherine Mary
author_facet Clarke, Katherine Mary
author_sort Clarke, Katherine Mary
title Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River
title_short Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River
title_full Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River
title_fullStr Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River
title_full_unstemmed Modeling the effects of climate change on streamflow and stream temperature in the South Fork of the Stillaguamish River
title_sort modeling the effects of climate change on streamflow and stream temperature in the south fork of the stillaguamish river
publisher Western CEDAR
publishDate 2020
url https://cedar.wwu.edu/wwuet/983
https://cedar.wwu.edu/context/wwuet/article/2008/viewcontent/Clarke_Thesis_Final.pdf
long_lat ENVELOPE(161.250,161.250,-77.567,-77.567)
geographic South Fork
geographic_facet South Fork
genre First Nations
genre_facet First Nations
op_source WWU Graduate School Collection
op_relation https://cedar.wwu.edu/wwuet/983
https://cedar.wwu.edu/context/wwuet/article/2008/viewcontent/Clarke_Thesis_Final.pdf
op_rights Copying of this document in whole or in part is allowable only for scholarly purposes. It is understood, however, that any copying or publication of this document for commercial purposes, or for financial gain, shall not be allowed without the author’s written permission.
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