Your search keyword '"Brad K. Bickford"' showing total 4 results

1. Performance of Subyearling Fall Chinook Salmon Tagged with 8‐, 9‐, and 12‐mm Passive Integrated Transponder Tags in the Snake River

Author

Dalton D. Lebeda, Brad K. Bickford, Kenneth F. Tiffan, William P. Connor, Frank L. Mullins, and Tobyn N. Rhodes

Subjects

Fishery, Chinook wind, Ecology, Management, Monitoring, Policy and Law, Aquatic Science, Biology, Ecology, Evolution, Behavior and Systematics, Transponder

Published

2021

2. Impact of smallmouth bass predation on subyearling fall Chinook salmon over a broad river continuum

Author

John M. Erhardt, Brad K. Bickford, Kenneth F. Tiffan, Rulon J. Hemingway, and Tobyn N. Rhodes

Subjects

0106 biological sciences, Chinook wind, food.ingredient, Consumption, Predation, Micropterus, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, Article, Percopsis transmontana, Bass (fish), food, Juvenile, Mortality, Ecology, Evolution, Behavior and Systematics, Snake River, biology, 010604 marine biology & hydrobiology, biology.organism_classification, Crayfish, Diet, Fishery, Oncorhynchus, Environmental science, sense organs

Abstract

Smallmouth bass (Micropterus dolomieu) predation on subyearling fall Chinook salmon (Oncorhynchus tshawytscha) was examined in the Snake River (USA) to identify seasonal and habitat-related changes in bass diets, and associated subyearling consumption and loss in various riverine and impounded reaches. Smallmouth bass diets reflected opportunistic foraging that at times showed predation on subyearlings is influenced by the consumption of other prey such as crayfish, sand roller (Percopsis transmontana), and smaller invertebrates. Estimated loss of subyearlings was influenced by bass abundance and consumption rates. The highest bass abundances (> 1,000 bass/river kilometer) were observed in the upper reach of Hells Canyon early in April and May, and in Lower Granite Reservoir. Peak consumption rates of subyearlings (≥ 0.12 subyearlings/bass/day) occurred in the upper reach of Hells Canyon during May and in most reservoir reaches in June. Predation losses accumulated evenly along the river continuum from riverine to reservoir habitats. We estimated that 869,371 subyearlings could be lost to smallmouth bass predation between riverine production areas and Lower Granite Dam in a given year. To provide a context for this estimated loss, we provide an illustration of its potential effect on the adult population. Assuming no juvenile mortality occurred downstream of the dam and depending on smolt-to-adult return rates, this represented up to 3.9–16.0% of the potential adult run that could have returned to Lower Granite Dam had no subyearling predation by smallmouth bass occurred upstream of the dam. Although this study was limited by a number of assumptions and constraints, it does provide an illustration of how predation affects juvenile and adult salmon loss over a broad, changing river landscape.

Published

2020

3. Fall Chinook Salmon (Oncorhynchus tshawytscha), Sand Roller (Percopsis transmontana), and Smallmouth Bass (Micropterus dolomieu) Interactions in a Snake River Reservoir: A Tale of Three Species

Author

Brad K. Bickford, Tobyn N. Rhodes, John M. Erhardt, Kenneth F. Tiffan, and Rulon J. Hemingway

Subjects

0106 biological sciences, Chinook wind, food.ingredient, biology, Micropterus, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, 010605 ornithology, Predation, Percopsis transmontana, Fishery, Bass (fish), food, Forage fish, General Earth and Planetary Sciences, Oncorhynchus, Diel vertical migration, General Environmental Science

Abstract

We studied some of the relationships between federally listed fall Chinook Salmon, Oncorhynchus tshawytscha, endemic Sand Roller, Percopsis transmontana, and non-native Smallmouth Bass, Micropterus dolomieu, in Lower Granite Reservoir on the Snake River. Because of its recent reappearance and population increase, the Sand Rollers could be filling the role of a “native invader” in the reservoir food web. We speculated that Sand Rollers could either negatively affect fall Chinook Salmon by potentially competing with them for resources in shoreline habitats or, alternatively, benefit the salmon by providing a buffer against Smallmouth Bass predation. Nighttime beach seining showed that habitat use by fall Chinook Salmon and Sand Rollers overlapped completely in spring when both species were present along shorelines. Diet data from stomach samples also showed high overlap, but data on stable isotopes of 13C and 15N suggested that each species could be obtaining much of their dietary energy from different reservoir locations. Although habitat and diet overlap are evidence of competition, diel and spatial partitioning of resource use between fall Chinook Salmon and Sand Rollers may act to reduce potential competition. Analyses of Smallmouth Bass diets showed that fall Chinook Salmon and Sand Rollers comprised the majority of prey fish consumed by bass. Across years, as Smallmouth Bass increased their consumption of Sand Rollers (range 0.219 to 0.392 fish smallmouth-1 day-1), they decreased their consumption of fall Chinook Salmon (range 0.114 to 0.050 fish smallmouth-1 day-1). The greatest effect Sand Rollers may have on fall Chinook Salmon in Lower Granite Reservoir is to serve as a buffer against Smallmouth Bass predation.

Published

2019

4. Ecology of the Opossum Shrimp (Neomysis mercedis) in a Lower Snake River Reservoir, Washington

Author

Kenneth F. Tiffan, Brad K. Bickford, and John M. Erhardt

Subjects

0106 biological sciences, Detritus, Ecology, 010604 marine biology & hydrobiology, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Food web, Predation, Shrimp, Fishery, Neomysis, Water column, Habitat, Benthic zone, Ecology, Evolution, Behavior and Systematics

Abstract

The opossum shrimp Neomysis mercedis has expanded its range from the lower Columbia River upstream 695 kilometers into Lower Granite Reservoir where it is now very abundant. We studied Neomysis ecology in the reservoir during 2011–2015 to better understand the physical and biological factors that shape their distribution as well as their potential role in the food web. Benthic densities in offshore habitats ranged from 19 to 145 mysids m-2 in shallow (2–12 m) water and from 3 to 48 mysids m-2 in deep (> 12 m) water. Water velocity, depth, substrate, and seasonal interactions were important variables for explaining variation in Neomysis densities in offshore habitats. During spring, daytime densities in shoreline habitats (< 2 m deep) were variable, but nighttime densities generally decreased in summer following reproduction and as temperatures approached 23 °C. Neomysis were mainly collected from the water column during nighttime vertical tows in the downstream end of the reservoir when water velocities were low during summer and autumn. Reproduction occurred mainly in spring and early summer, but a second, smaller reproductive event was observed during autumn. The diet of Neomysis consisted primarily of detritus, rotifers, and copepods, but cladocerans were more prominent during summer and autumn. Physical factors like water velocity may have limited vertical migrations of Neomysis to feed in the water column and influenced use of different habitats in the reservoir. Neomysis are prey for a number of species, including juvenile salmon, but their relations are still largely unknown, and continued monitoring and research is warranted.

Published

2017