light & heat in inland waters. light spectrum at the top and bottom of the atmosphere

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  • Slide 1
  • LIGHT & HEAT IN INLAND WATERS
  • Slide 2
  • Light spectrum at the top and bottom of the atmosphere
  • Slide 3
  • Measurable Properties of Light Intensity Quality Both are dependent on absorption and reflection by the atmosphere
  • Slide 4
  • Fates of light in water
  • Slide 5
  • Shading of low order streams
  • Slide 6
  • Confluence of Kotorosl and Volga Rivers
  • Slide 7
  • Walker Lake
  • Slide 8
  • Extinction Coefficient (nu) = extinction coefficient of light through water. Examples: Crystal Lake v = 0.19 Turbid Pond v = 1 10 Muddy Stock Tank v = >>10-150 Depends on: Light absorption by water Light scattered and absorbed by particles Light absorbed by dissolved substances v ~ 1/secci depth
  • Slide 9
  • Secci Disk
  • Slide 10
  • Typical Secci Depths Crater Lake 40m Castle Lake 33m Lake Texoma 0.75m Susquehanna River West Shore >1.2m West Center 0.32m East Center 0.23m East Shore 0.18m Secci Depth measured with Secci Disk in lakes and with a Secci Tube in running water. Also measured with Turbidimeter (JTU)
  • Slide 11
  • Susquehanna River at Byers Island
  • Slide 12
  • Lakes Erie and St. Claire following major runoff event
  • Slide 13
  • Heat Budget for Lakes Sources Solar radiation Sensible heat conduction Stream Input Sediment absorption of sunlight Geothermal Biogenic Sinks Evaporation Sensible heat conduction Back radiation from lake surface Stream inputs (snow melt) Surface outflow
  • Slide 14
  • Annual Lake Heat Budget whereS = storage rate of heat in the lake R n = net radiation E = evaporation H = sensible heat transfer, conduction Q = advective heat transfers due to water inflows and outflows S = R n E H Q
  • Slide 15
  • Slide 16
  • Lake Tahoe, CA-NV
  • Slide 17
  • Lake Mendota, WI
  • Slide 18
  • Density and temperature
  • Slide 19
  • Stratification
  • Slide 20
  • Castle Lake Stratification
  • Slide 21
  • Slide 22
  • Lake Classification Based on Thermal Stratification Patterns 1.Holomixis a.monomictic mixes once per year warm monomictic never below 4C cold monomictic never above 4C ex: Lake Tahoe -large volume and large depth -no winter ice cover
  • Slide 23
  • Fall turnover occurs when the center of gravity (M) approaches the center of the volume (X).
  • Slide 24
  • Slide 25
  • Martin Lake
  • Slide 26
  • Slide 27
  • b.dimictic mixes twice per year ex: Castle Lake and Lake Mendota small temperate lake freezes over during winter c.amictic does not mix, permanently ice- covered ex: Lake Vanda, Antarctic high latitude lake
  • Slide 28
  • Lake Vanda, Antarctica
  • Slide 29
  • Slide 30
  • Meromixis
  • Slide 31
  • Lake Nyos
  • Slide 32
  • Lakes Nyos (A&C) and Monoun (B&D)
  • Slide 33
  • Polymixis in Clear Lake (Rueda et al. 2003)
  • Slide 34
  • PropertyRiversReservoirsLakes Temperature variationsRapid, largeRapid in upper zone; slow in lower portion Slow, stable StratificationRareIrregularCommon (monomictic or dimictic) Spatial differencesHeadwaters cooler becoming warmer downstream Large fluctuations in upper reservoir, more stable in main body Stratification common Groundwater effectsHigh ratio groundwater to runoff SmallUsually small (high in seepage lakes) Tributary effectsCan be significantModerate to smallSmall and localized Shading effectsConsiderable, especially in the headwaters Small to negligible Winter ice formationTransitoryUsually transitoryPersistent Ice scouring effectsExtensiveMinor