Chezik, Kyle August2013-11-112013-11-112013-08https://hdl.handle.net/11299/160062University of Minnesota M.S. thesis. August 2013. Major: Conservation Biology. Advisor: Paul A. Venturelli. 1 computer file (PDF); viii, 65 pages.Ectotherm growth and development are largely a function of temperature. Within the range of thermal tolerance, growth and development increases linearly over a mid-range of temperatures. Degree-days (DD; &deg;C;days) are a method of quantifying the thermal experience of an organism over the linear range and are an increasingly popular method for describing growth and development in fish. To limit degree-day calculations to temperatures within the linear range, a lower temperature threshold (T<sub>o</sub>) is incorporated that defines the onset of growth. However, there is currently no convention for choosing T<sub>o</sub> and the implications of choosing an inappropriate T<sub>o</sub> are largely unknown. This uncertainty has resulted in a wide range of T<sub>o</sub> values currently in use both among- and within-species. In this thesis I explore i) how T<sub>o</sub> affects the ability of DD to explain within-population variation in fish growth, and ii) the effect of T<sub>o</sub> on apparent growth among populations in thermally dissimilar environments. To address these objectives, I first use simulated data to determine the theoretical relationship between T<sub>o</sub> and growth. I then demonstrate these theoretical relationships using immature length-at-age data from 8 species and 85 waterbodies in Minnesota USA and Ontario Canada. My results show that DD at low T<sub>o</sub> are highly correlated and that these highly correlated low T<sub>o</sub> values explain variation in growth equally well within a single population. Furthermore, growth rates among populations of thermally dissimilar habitat become increasingly dissimilar as T<sub>o</sub> deviates from the T<sub>o</sub> that minimizes the variation in growth rate among populations. This effect is especially apparent when the among-population range in thermal habitats is large. These findings suggest that, although T<sub>o</sub> matters little when accounting for variation in growth within a single population, an inappropriate T<sub>o</sub> can lead to the appearance of among-population differences in growth. When choosing T<sub>o</sub>, I recommend estimating T<sub>o</sub> using the Charnov and Gillooly (2003) &ldquo;10&deg;C rule&rdquo; and then rounding to the nearest T<sub>o</sub> standard (0, 5, 10 and 15&deg;C). Choosing a T<sub>o</sub> standard in this way will minimize the effect of T<sub>o</sub> error on growth bias in among-population studies. In general, standardization i) simplifies T<sub>o</sub> identification, ii) facilitates comparative studies, and ii) promotes the use of DD in future studies.en-USDegree-dayGrowthThermal timeThermal unitThresholdWalleyeFish growth and degree-days: Advice for selecting base temperatures in both within- and among-lake studiesThesis or Dissertation