Chamberlin DW, Knight CT, Kraus RT, Gorman AM, Xu W, Collingsworth PD. Hypoxia augments edge effects of water column stratification on fish distribution. Fish Res. 2020;231:105684.
Cherry DS, Dickson KL, Cairns Jr J, Stauffer JR. Preferred, avoided and lethal temperatures of fish during rising temperature conditions. J Fish Res Board Can. 1977;34(2):239-246.
Chowdhury MR, Wells MG, Howell T. Movements of the thermocline lead to high variability in benthic mixing in the nearshore of a large lake. Water Resour Res. 2016;52(4):3019-3039.
Coker GA, Portt CB, Minns CK. Morphological and ecological characteristics of Canadian freshwater fishes. Can. MS Rpt. Fish Aquat. Sci. 2554: iv+89p. 2001.
Cooke SJ, Hinch SG, Wikelski M, Andrews RD, Kuchel LJ, Wolcott TG, et al. Biotelemetry: a mechanistic approach to ecology. Trends Ecol Evol. 2004;19(6):334-343.
Flood B, Wells MG, Midwood JD, Brooks J, Kuai Y, Li J. Intense variability of dissolved oxygen and temperature in the internal swash zone of Hamilton Harbour, Lake Ontario. Inland Waters. 2021. p. 1-18.
Guzzo MM, Blanchfield PJ, Rennie MD. Behavioral responses to annual temperature variation alter the dominant energy pathway, growth, and condition of a cold-water predator. P Natl Acad Sci USA. 2017;114(37):9912–9917.
Hasnain S, Minns C, Shuter B. Key ecological temperature metrics for Canadian freshwater fishes. Applied Research and Development Branch, Ministry of Natural Resources. 2010.
Hokanson KEF. Temperature Requirements of Some Percids and Adaptations to the Seasonal Temperature Cycle. J Fish Res Board Can. 1977;34(10):1524–1550.
Huang A, Rao YR, Lu Y, Zhao J. Hydrodynamic modeling of Lake Ontario: An intercomparison of three models. J Geophys Res-Oceans. 2010;115(C12).
Hussey NE, Kessel ST, Aarestrup K, Cooke SJ, Cowley PD, Fisk AT, et al. Aquatic animal telemetry: a panoramic window into the underwater world. Science. 2015;348(6240):1255642-1255642.
Ivanova SV, Johnson TB, Metcalfe B, Fisk AT. Spatial distribution of lake trout (Salvelinus namaycush) across seasonal thermal cycles in a large lake. Freshwater Biol. 2020;66(4):615-627.
Kessel ST, Cooke SJ, Heupel MR, Hussey NE, Simpfendorfer CA, Vagle S, et al. A review of detection range testing in aquatic passive acoustic telemetry studies. Rev Fish Biol Fisher. 2014;24(1):199-218.
Klinard NV, Halfyard EA, Matley JK, Fisk AT, Johnson TB. The influence of dynamic environmental interactions on detection efficiency of acoustic transmitters in a large, deep, freshwater lake. Anim Biotelemetry. 2019;7(1):1-17.
Klinard NV, Matley JK, Halfyard EA, Connerton M, Johnson TB, Fisk AT. Post‐stocking movement and survival of hatchery‐reared bloater (Coregonus hoyi) reintroduced to Lake Ontario. Freshwater Biol. 2020;65(6):1073-1085.
Klump JV, Brunner SL, Grunert BK, Kaster JL, Weckerly K, Houghton EM, et al. Evidence of persistent, recurring summertime hypoxia in Green Bay, Lake Michigan. J Great Lakes Res. 2018;44(5):841-850.
Kraud RT, Knight CT, Farmer TM, Gorman AM, Collingsworth PD, Warren GJ, et al. Dynamic hypoxic zones in Lake Erie compress fish habitat, altering vulnerability to fishing gears. Can J Fish Aquat Sci. 2015;72(6):797-806.
Loher T, Webster RA, Carlile D. A test of the detection range of acoustic transmitters and receivers deployed in deep waters of Southeast Alaska, USA. Anim Biotelemetry. 2017;5(1):1-22.
Magnuson JJ, Crowder LB, Medvick PA. Temperature as an ecological resource. Integr Comp Biol. 1979;19:331–343.
Mathies NH, Ogburn MB, McFall G, Fangman S. Environmental interference factors affecting detection range in acoustic telemetry studies using fixed receiver arrays. Mar Ecol Prog Ser. 2014;495:27-38.
Minns CK, King SW, Portt CB. Morphological and ecological characteristics of 25 fishes occurring in Great Lakes' Areas of Concern. Can. MS Rpt. Fish Aquat. Sci. 2209: vi + 25p. 1993.
O’Brien M, Secor D. Influence of thermal stratification and storms on acoustic telemetry detection efficiency: a year-long test in the US Southern Mid-Atlantic Bight. Anim Biotelemetry, 2021;9(1):1–12.
Peterson RH, Sutterlin AM, Metcalfe JL. Temperature preference of several species of Salmo and Salvelinus and some of their hybrids. J Fish Res Board Can. 1979;36:1137-1140.
Porter MB. The Bellhop manual and user’s guide: Preliminary draft. Heat, Light, and Sound Research, Inc., La Jolla, CA, USA, Tech. Rep. 2011.
Raby GD, Johnson TB, Kessel ST, Stewart TJ, Fisk AT. Pop-off data storage tags reveal niche partitioning between native and non-native predators in a novel ecosystem. J Appl Ecol. 2019;57(1):181-191.
Roberts JJ, Höök TO, Ludsin SA, Pothoven SA, Vanderploeg HA, Brandt SB. Effects of hypolimnetic hypoxia on foraging and distributions of Lake Erie yellow perch. J Exp Mar Biol Ecol. 2009;381:S132-S142.
Rodgers GK. Time of onset of full thermal stratification in Lake Ontario in relation to lake temperatures in winter. Can J Fish Aquat Sci. 1987;44(12):2225-2229.
Scott WB, Crossman EJ. Freshwater fishes of Canada. Fisheries Research Board of Canada. Bulletin 183. Ottawa, Canada. 1973.
Shi H, Kruger D, Nickerson JV. Incorporating environmental information into underwater acoustic sensor coverage estimation in estuaries. IEEE Milit Commun C. 2007. p. 1-7.
Urick RJ. Principles of underwater sound. Baskerville: Peninsula Publishing. 1983.
Wells MG, Li J, Flood B, Brooks JL, Cooke SJ, Kuai Y, et al. Speed-of-sound gradients due to summer thermal stratification can reduce the detection range of acoustic fish tags: results from a field study in Hamilton Harbour, Ontario. Can J Fish Aquat Sci. 2021;78(3):269-285.
Wismer DA, Christie AE. Temperature relationships of Great Lakes fishes: a data compilation. Great Lakes Fish Comm Spec Pub 87-3. 165 p. 1987.
Yang B, Young J, Brown L, Wells MG. High‐frequency observations of temperature and dissolved oxygen reveal under‐ice convection in a large lake. Geophys Res Lett. 2017;44(24):12218-12226.
Yang B, Wells MG, Li J, Young J. Mixing, stratification, and plankton under lake‐ice during winter in a large lake: Implications for spring dissolved oxygen levels. Limno Oceanogr. 2020;65(11):2713-2729.