Transcript Document

Stream Ecology
Habitat characteristics determines species richness and community composition in aquatic ecosystems:
• Physicochemical parameters of the water
• Hydromorphological and structural feature of the physical habitat
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Geomorphological features of the stream: flow velocity, substrate, river bank, sedimentation,
connection with lateral systems and with the hyporheic zone…
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Climate: temperature, extreme events, flow discharge, sunshine…
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Connection with the stream vegetation and the riparian zones: flux of energy and organic matter,
areas for feeding and reproduction, shadow…
Inter-dependent, finely tuned and variable properties
Heavily impacted by human activities: water depth, flow regime, river bed morphology…
Species-specific preference and tolerance for the different parameters of the physical habitat
Morphohydraulic parameters are the major drivers of physical habitat
Patchy mosaic of habitats and micro-habitats
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Swift flow areas: coarse substrate, rheophil, oxyphil or cryophil species (1 to 3)
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Slow-moving sections: deep water, fine substrate, lentic environment, limnophil species (4)
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2
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Thymallus thymallus
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Stream Ecology
Local species richness in rivers depends on habitat heterogeneity
 Longitudinal: gradients in water depth and velocity
 Lateral: meanders, river arms, channel dissymmetry (5)
spawning area, nurseries, habitats for lentic species…
 Vertical: substrate permeability
exchange of water and organic matter
trapping of pollutants
 Temporal: variable flow rate, flooding
 Connection with the riparian zone: sharp environmental gradients,
buffer zone, ecological corridors, mosaic of landforms… (6 to 10)
submersed dead wood as micro-habitats
roots as important resting sites and egg-laying sites
Troglodytes troglodytes
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Cinclus cinclus
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Tinca tinca
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Open, non-equilibrium ecosystems dynamically linked longitudinally,
laterally and vertically by hydrological and geomorphic processes occurring
within a temporal hierarchy
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Squalius cephalus
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Esox lucius
The River Continuum Concept
The distribution of organisms - resources - biological processes change along rivers and depend on
large-scale and local processes
• Stream Zonation Concept (Illies & Botosaneanu 1963)
A series of distinct communities along rivers
• River Continuum Concept (Vannote et al 1980)
 River communities and metabolism are
influenced by local conditions and by processes
occurring upstream
 Rivers as integrated systems within the landscape
• Hyporrheic Corridor Concept (Stanford & Ward 1993)
Hydrological and functional connections between the river
and the riparian zone extend to the entire alluvial bed
• Flood Pulse Concept (Junk et al. 1989)
 Comprehensive approach focusing on river
floodplain dynamics
 Rivers and their associated floodplains are
integrated components of a single dynamic
system
Dams and hydropower production:
 Loss of connectivity between compartments
 All four dimensions of stream ecosystems disrupted
Vannote et al. (1980) The River Continuum Concept.
Canadian Journal of Fisheries and Aquatic Sciences 7(1): 130-137
Ecological Effects of Water Reservoirs
Pike spawning ground
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Anguilla anguilla
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Lampetra sp.
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Salmo trutta
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Ecological effects upstream and downstream of reservoirs
• Upstream: change in river discharge and morphology
 Complete switch of the community from lotic to lentic
 Contamination of water and sediment from the stream watershed
• Downstream: reduced or no base flow
 Effects on river bank habitats and connections with lateral
compartments (11)
 Reduced flushing of particles and amplified thermal fluctuations
• Along the entire stream:
 No stream continuity for upstream and downstream migrations
 Habitat fragmentation and isolated populations (12 to 14)
 Impaired trophic interactions
• Hydro- and thermopeaking: rapid fluctuations in flow discharge and
temperature resulting from hydropower plant operation
 Increase in shear stress
 Clogging or erosion of the sediment bed and river banks
 Flooding of spawning and nursery areas
 Altered lateral connectivity
 Change in the chemical and physical properties of the water
Alteration of five critical components: magnitude of discharge, frequency
of occurrence of flow, duration of specific high or low flow conditions,
timing or predictability of flows and rate of flow change
Flow Alteration
Effects on abiotic parameters in watercourses
• Rapid and significant changes in hydraulics:
 Discharge
 Flow velocity
 Bed shear stress
• Chemical and physical water quality:
 Diurnal cycle of turbidity and temperature
 Conductivity
 Concentration of nutrients and contaminants
• Morphology:
 Movement of an overlying fine gravel layer
 Suspension or deposition of fine sediments
 Grain distribution
Meile et al. (2005)
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Synthesebericht Schwall/Sunk. Publikation des Rhone-Thur-Projekts
Changes in abiotic factors influence biotic communities
• Rapidity of change: cannot be sensed by organisms
• Change in composition (15-16) (e.g. Pof and Alan 1995 Ecology 76)
• Decline in abundance or biomass
 Fish, benthic macro-invertebrates and algae
 Riparian fauna
• Stranding of organisms and increased drift density
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Reduced exchanges with the hyporheic zone
• Water table lowering
• Riverbed clogging
Berry and Hill (2003) The biological effects of suspended and bedded
sediment in aquatic systems: a review. USEPA Internal Report
Thermal Alteration
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The ecological integrity of lotic systems depends
on the natural dynamics of the thermal regime
Ecological consequences of modified regimes
• Altered spawning opportunities and success of
native fish species
• Reduced growth rates
17 turnover
• Decline of native species and species
• Effects on invertebrate communities
 Reduced developmental cues
 Asynchrony of life cycle and resources
 Changes in assemblage structure (17)
Olden and Naiman (2010) Incorporating thermal regimes into environmental flows
assessments: modifying dam operations to restore freshwater ecosystem integrity.
Freshwater Biology 55:86-107
Drift Responses Of Benthic Invertebrates
Sudden releases of hypolimnetic water also cause thermopeaking
• Large dams: highly variable and frequently depressed summer water temperatures
• Smaller dams: increases in downstream temperatures
Drift
response
to hydropeaking
• Flow
is a major
determinant of physical
• Species-specific
differences
driftisabundance
habitat in streams, which ininturn
a major (18) (e.g. Mochizuki et al. 2006 Limnology)
• Use
of refugia of
during
disturbance (19-20) (e.g. Lancaster 1999 Freshwater Biology)
determinant
bioticflow
composition
• • Importance
of thehave
rateevolved
of increase
in flow (e.g. Imbert and Perry 2000 Hydrobiologia)
Aquatic species
life history
• Sediment
mass driftto(e.g. Gibbins et al. 2007 Can. J. Fish. Aquat. Sci.)
strategiesmovement
primarily intriggers
direct response
• Changes
in taxa
diversity
and abundance (e.g. Bruno et al. 2009 Ann. Limnol.)
their natural
flow
regimes
• Maintenance
of
Interactive
effectsof
ofnatural
hydro- patterns
and thermopeaking
longitudinal drift
and lateral
connectivity
is drift (e.g. Bruno et al. 2012 Ecohydrology)
• Catastrophic
followed
by behavioral
essentialeffects
to the viability of populations of
• Synergic
many riverinedifferences
species in response to hydro- and thermopeaking
• Taxon-specific
• The invasion and success of exotic and
introduced species in rivers is facilitated by
the alteration of flow regimes
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19
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Bunn and Arthington (2002) Basic Principles and Ecological Consequences of Altered Flow
Regimes for Aquatic Biodiversity. Environmental Management 30(4):492-507
Bruno et al. (2013) Multiple drift responses of benthic
invertebrates to interacting hydropeaking and thermopeaking
waves. Ecohydrology 6(4):511-522
Photo Credits
(1) www.maxisciences.com
(2) www.plymouth.edu
(3) www.luontoportti.com
(4) www.louisbourdon.com
(5) Biodiversité et caractéristiques physiques des cours d’eau (Jean-Claude Philippart)
(6) www.wise-photographie.e-monsite.com
(7) www.geowi.skynetblogs.be
(8) www.zoomalia.com
(9) www.droidcorps.com
(10) www.pnr-scarpe-escaut.fr
(11) Guide technique pour la restauration des frayères à brochet UFBAG (Laurent Rougerie)
(12) www.naturfoto.cz
(13) www.infohightech.com
(14) www.calvados-littoral.f
(15) www.imgkid.com
(16) www.desman-pyrenees.com
(17-18) www.wikipedia.org
(19) www.discoverlife.org
(20) www.biopix.com