scholarly journals Comparing headwater stream thermal sensitivity across two contrasting lithologies in Northern California

2021 ◽  
Author(s):  
Austin Wissler ◽  
Catalina Segura ◽  
Kevin Bladon
Keyword(s):  
Air Temperature ◽  
Sustainable Forest Management ◽  
Headwater Streams ◽  
Thermal Sensitivity ◽  
Groundwater Discharge ◽  
Ecological Condition ◽  
Cascade Range ◽  
Northern California ◽  
Coast Range ◽  
Thermal Regimes

Understanding drivers of thermal regimes in headwater streams is critical for a comprehensive understanding of freshwater ecological condition and habitat resilience to disturbance, and to inform sustainable forest management policies and decisions. However, stream temperatures may vary depending on characteristics of the stream, catchment, or region. To improve our knowledge of the key drivers of stream thermal regime, we collected stream and air temperature data along eight headwater streams in two regions with distinct lithology, climate, and riparian vegetation. Five streams were in the Northern California Coast Range at the Caspar Creek Experimental Watershed Study, which is characterized by permeable sandstone lithology. Three streams were in the Cascade Range at the LaTour Demonstration State Forest, which is characterized by fractured and resistant basalt lithology. We instrumented each stream with 12 stream temperature and four air temperature sensors during summer 2018. Our objectives were to compare stream thermal regimes and thermal sensitivity—slope of the linear regression relationship between daily stream and air temperature—within and between both study regions. Mean daily stream temperatures were ~4.7 °C warmer in the Coast Range but were less variable (SD = 0.7 °C) compared to the Cascade Range (SD = 2.3 °C). Median thermal sensitivity was 0.33 °C °C in the Coast Range and 0.23 °C °C in the Cascade Range. We posit that the volcanic lithology underlying the Cascade streams likely supported discrete groundwater discharge locations, which dampened thermal sensitivity. At locations of apparent groundwater discharge in these streams, median stream temperatures rapidly decreased by 2.0 °C, 3.6 °C, and 7.0 °C relative to adjacent locations, approximately 70–90 meters upstream. In contrast, thin friable soils in the Coast Range likely contributed baseflow from shallow subsurface sources, which was more sensitive to air temperature and generally warmed downstream (up to 2.1 °C km). Our study revealed distinct longitudinal thermal regimes in streams draining contrasting lithology, suggesting that streams in these different regions may respond differentially to forest disturbances or climate change.

Catastrophic disturbances in headwater streams: the long-term ecological effects of debris flows and debris floods in the Klamath Mountains, northern California

2010 ◽  
Vol 67 (10) ◽  
pp. 1596-1610 ◽  
Author(s):  
Matthew R. Cover ◽  
Juan A. de la Fuente ◽  
Vincent H. Resh
Keyword(s):  
Debris Flow ◽  
Debris Flows ◽  
Headwater Streams ◽  
Ecological Effects ◽  
Ecosystem Structure ◽  
Northern California ◽  
Klamath Mountains ◽  
Mountainous Landscapes ◽  
Debris Floods

Debris flows and debris floods are catastrophic disturbances in steep, mountainous landscapes throughout the world, but little is known about the long-term ecological effects of these events on headwater streams. In 10 basins (10–20 km2) in the Klamath Mountains, northern California, USA, we used a space-for-time substitution to infer the long-term (10–100 years) effects of debris flows on stream ecosystem structure. Debris flows mobilized sediment and wood and removed riparian vegetation from large portions of channel networks. Stream temperatures were significantly warmer in streams that had recent debris flows (<10 years ago). Large wood, benthic organic matter, and detritivorous stoneflies were all very sparse in recent debris flow streams, suggesting that allochthonous energy pathways took decades to recover. Rainbow trout ( Oncorhynchus mykiss ) were abundant in recent debris flow streams, but populations of other vertebrates such as coastal giant salamander ( Dicamptodon tenebrosus ) and coastal tailed frog ( Ascaphus truei ) were virtually absent. Increased frequencies of catastrophic debris flows associated with forest management practices can have significant negative impacts on aquatic biodiversity in forested, mountainous landscapes.

scholarly journals Factors of lowering the Lake Syne levels and measures to improve its ecological state

2020 ◽  
pp. 101-111
Author(s):  
O. M. Kozytskyi ◽  
S. A. Shevchuk ◽  
I. A. Shevchenko ◽  
N. V. Logunova
Keyword(s):  
Water Content ◽  
Air Temperature ◽  
Catchment Area ◽  
Negative Impact ◽  
Ecological Condition ◽  
Water Levels ◽  
Annual Rainfall ◽  
Anthropogenic Pressure ◽  
Ecological State ◽  
Positive Balance

Relevance of research. The consequences of the intensive rise in air temperature can be clearly seen in the example of shallowing natural reservoirs in which, unlike ponds and reservoirs, there it is impossible to regulate runoff. This, in particular, applies to Syne Lake, located on the northwestern outskirts of Kyiv. Since the middle of the last century, the lake and the area around it have undergone significant anthropogenic pressure, which has had a negative impact on its ecological condition. The development of a comprehensive system of measures to improve the ecology of the lake requires a thorough study of the main factors in the formation of the hydrological regime of the reservoir and their discrete assessment. Objective of research is to identify natural and man-made factors that have led to a significant decrease in the Syne Lake levels in recent years and to develop of measures to improve its ecological state. Research results. The increase in evaporation from the water surface, the decrease in precipitation and inflow from the catchment caused a significant decrease in water levels in the lake and its morphological parameters. Since 2001, the area of ​​the water mirror has decreased from 3.4 ha to 2.6 ha, the water level has decreased by more than 1 m, and the shore horizon has shifted to the middle by more than 10 m. The decrease in the water content of the lake was due to changes in the components of its water balance, which was directly affected by factors, both natural and man-made.  As a result of road construction and intensive development of the area around the lake, the catchment area decreased from 758 ha to 21 ha, which caused a sharp decrease in surface runoff to the lake. A modern network of drainage and stormwater systems within the natural catchment area of ​​the lake provides drainage into the Dnieper River. The lake overgrowing and siltation by 1-1.5 m led to clogging of underground springs and, accordingly, to a decrease in pressure underground supply. Other reasons for the lake shallowing are a decrease in precipitation and an increase in air temperature. Having a climatic standard 649 mm in Kyiv in 2019, only 521 mm fell, and in general for the last 5 years the annual rainfall has decreased by an average of 87 mm per year. The average air temperature compared to the climatic standard over the past 10 years has increased by 1.9 °C, and in the hot 2019 - by 2.9 °C, which led to a significant increase in evaporation. Compared to the climatic standard, evaporation from the surface of Kyiv reservoirs has increased over the last 10 years by 127 mm, and in 2019 it reached a record rate of 911 mm. Only due to the increased evaporation from the surface of the lake and reduced rainfall, the lake level in 2019 decreased by 30.4 cm. The results of the performed research show that for the last 5 years the positive balance of moisture in the catchment is maintained. The total amount of precipitation is 161 mm higher than the evaporation for the same period, but it is 2.4 times less than the climatic standard. In low water years as it was 2015 and 2019, the difference between precipitation and evaporation from the catchment area was only 13 and 20 mm, while in the period of 1961-1990 it was 69 mm. This led to a decrease in groundwater levels and, consequently, a decrease in their inflow to the lake. Conclusion. Intensive reduction of the water content of Syne Lake is due to a complex of natural and man-made factors, including the redistribution of runoff outside the catchment as a result of building in the area, siltation of underground feeding sources, reducing rainfall and increasing evaporation due to rising air temperatures. Reducing the intensity of lake shallowing is possible by increasing the inflow of water, by redirecting to the lake surface (after treatment) and drainage runoff from the natural catchment area of ​​the lake and beyond. Clearing and dredging the lake will increase its depth and improve groundwater inflow.

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