Figure 1.
Particular matter C∶N ratios increase with tmeperature and decrease with dilution rate.
Molar C∶N ratios of particulate, organic matter in response (log10-scale) to temperature and nutrient regime; N1: 50% dilution three times per week; N2: 25% dilution three times per week; N3: no dilution.
Figure 2.
Phytoplankton community mean cell size decreases with temperature and increases with dilution rate.
Community mean cell volume in µm3 (log10-scale) in response to temperature and nutrient regime; N1: 50% dilution three times per week; N2: 25% dilution three times per week; N3: no dilution.
Figure 3.
Cell sizes of phytoplankton taxa decrease with temperature and increase with dilution rate.
Cell volume in µm3 (log10-scale) in response to temperature and nutrient regime; N1: 50% dilution three times per week; N2: 25% dilution three times per week; N3: no dilution. Species codes: CT: Ceratium tripos; CF: Ceratium fusus; PR: Prorocentrum micans; AP: Amphidinium sp.; CHB: Chaetoceros brevis; DC: Dictyocha speculum; SC: Scrippsiella trochoidea; CP: Cerataulina pelagica; TH: Thalassionema nitzschioides.
Figure 4.
Cell sizes of phytoplankton taxa decrease with temperature and increase with dilution rate
(continued). Cell volume in µm3 (log10-scale) in response to temperature and nutrient regime; N1: 50% dilution three times per week; N2: 25% dilution three times per week; N3: no dilution. Species codes: GY: Gymnodinium sp.; LD: Leptocylindrus danicus; CHC: Chaetoceros curvisetus; PY: Pyramimonas sp.; CC: Cylindrotheca closterium; PC: picophytoplankton.
Table 1.
ANOVA of temperature and nutrient effects.
Table 2.
Regression analysis of temperature-size relationships.
Table 3.
Multiple Regression of cell volume on temperature and C∶N ratios.