Kelsey Lucas
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View article: Effects of ceratotrichia diameter and packing density on chimaera pectoral fin kinematics
Effects of ceratotrichia diameter and packing density on chimaera pectoral fin kinematics Open
Chimaeras – an ancient group of cartilaginous fishes – swim by flapping their pectoral fins in a distinctive locomotory mode, termed flapping flight, that induces an undulatory wave traveling from the leading edge to the trailing edge of t…
View article: Ontogeny of escape response and body shape in Threespine Stickleback (<i>Gasterosteus aculeatus</i> L.)
Ontogeny of escape response and body shape in Threespine Stickleback (<i>Gasterosteus aculeatus</i> L.) Open
Escape responses in fishes provide insight into accelerative motions and behavioral response times of these animals, linking numerous fitness-related traits. We sought to connect escape response performance to genotype and phenotype across…
View article: Anthropogenic stressors and the marine environment: From sources and impacts to solutions and mitigation
Anthropogenic stressors and the marine environment: From sources and impacts to solutions and mitigation Open
Human-released contaminants are often poorly understood wholistically in marine ecosystems. This review examines the sources, pathways, impacts on marine animals, and mitigation strategies of five pollutants (plastics, per- and polyfluoroa…
View article: Flexibility is a hidden axis of biomechanical diversity in fishes
Flexibility is a hidden axis of biomechanical diversity in fishes Open
Nearly all fish have flexible bodies that bend as a result of internal muscular forces and external fluid forces that are dynamically coupled with the mechanical properties of the body. Swimming is therefore strongly influenced by the body…
View article: Jellyfish and Fish Solve the Challenges of Turning Dynamics Similarly to Achieve High Maneuverability
Jellyfish and Fish Solve the Challenges of Turning Dynamics Similarly to Achieve High Maneuverability Open
Turning maneuvers by aquatic animals are essential for fundamental life functions such as finding food or mates while avoiding predation. However, turning requires resolution of a fundamental dilemma based in rotational mechanics: the forc…
View article: Airfoil-like mechanics generate thrust on the anterior body of swimming fishes
Airfoil-like mechanics generate thrust on the anterior body of swimming fishes Open
The anterior body of many fishes is shaped like an airfoil turned on its side. With an oscillating angle to the swimming direction, such an airfoil experiences negative pressure due to both its shape and pitching movements. This negative p…
View article: Surface pressure and swimming force calculation data for bluegill and trout steadily swimming at 2.5 L/s
Surface pressure and swimming force calculation data for bluegill and trout steadily swimming at 2.5 L/s Open
Data involved in force calculation by bluegill sunfish and brook trout steadily swimming in the carangiform mode at 2.5 L/s. Includes videos of swimming fishes, body depth profiles, ventral view outlines, velocity vector fields calculated …
View article: The fish body functions as an airfoil: surface pressures generate thrust during carangiform locomotion
The fish body functions as an airfoil: surface pressures generate thrust during carangiform locomotion Open
The anterior body of many fishes is shaped like an airfoil turned on its side. With an oscillating angle to the swimming direction, such an airfoil experiences negative pressure due to both its shape and pitching movements. This negative p…
View article: trout4_2.5BLs_4_ventral_frm683-907_00753.tab
trout4_2.5BLs_4_ventral_frm683-907_00753.tab Open
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View article: B00093.dat
B00093.dat Open
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View article: B00253.dat
B00253.dat Open
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View article: B00325.dat
B00325.dat Open
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View article: yvalsBound.dat
yvalsBound.dat Open
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View article: klbg4_2.5BLs_3_ventral_frm1-277_00241.tab
klbg4_2.5BLs_3_ventral_frm1-277_00241.tab Open
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View article: B00496.dat
B00496.dat Open
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View article: trout4_2.5BLs_4_ventral_frm189-447_00369.tab
trout4_2.5BLs_4_ventral_frm189-447_00369.tab Open
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View article: B00108.dat
B00108.dat Open
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View article: klbg4_2.5BLs_1_ventral_frm681-980_00681.tab
klbg4_2.5BLs_1_ventral_frm681-980_00681.tab Open
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View article: queen2_dT10ms_00701.dat
queen2_dT10ms_00701.dat Open
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View article: queen2_dT10ms_00548.dat
queen2_dT10ms_00548.dat Open
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View article: pressures.dat
pressures.dat Open
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View article: B00499.dat
B00499.dat Open
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View article: B00185.dat
B00185.dat Open
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View article: B00763.dat
B00763.dat Open
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View article: klbg4_2.5BLs_3_ventral_frm1-277_00091.tab
klbg4_2.5BLs_3_ventral_frm1-277_00091.tab Open
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View article: B00189.dat
B00189.dat Open
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View article: queen2_dT10ms_00529.dat
queen2_dT10ms_00529.dat Open
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View article: queen2_dT10ms_00600.dat
queen2_dT10ms_00600.dat Open
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View article: queen2_dT10ms_00618.dat
queen2_dT10ms_00618.dat Open
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View article: queen2_dT10ms_00193.dat
queen2_dT10ms_00193.dat Open
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