Geomorphology
Erosion
• bank and bed erosion - stabilizing role of plant root systems
* critical erosion capacity
= the lowest velocity needed for a transport of a particle of a given size
- lowest for sand (ca 20 cm s_1)
Before
Measure pin exposure (width)
After
>> ra
O
			se		03		les	ibble
			i_ (D	T3 C			bb	
CO	lE	es	O O	es	O	an	pe	cr:
o
DC
1000
Erosion |v velocity
E
u
o o
3
100
10
1 0
0 001   0 01
0.1      1.0 10 Size (mm)
100 1000
FIGIRF 3.8 Relation of mean current velocity in water at least 1 m deep to the size of mineral grains that can be eroded from a bed of material of similar size. Below the velocity sufficient tor erosion of grains of a given size (shown as a band), grains can continue to be transported. Deposition occurs at lower velocities than required for erosion of a particle of a given size. (Reproduced from MorLsawa 1968.)
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Geomorphology
Sediment load
• Suspended load (plaveniny) - usually majority of the total load (5-50 x more than bedload), increases turbidity
• Bedload (splaveniny) -<5-10% of the total load but strong impact on the channel shape
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Geomorphology
Sediment load
• Washload - 0.5 u.m-0.625 mm, clay, silt and very fine sand, may never settle out
r~ Washload
Total Load {defined by source)
— Suspended load —i
i— In suspension —I
'—Bed material load
— Along the bed
Bed load
Total load (defined by mode of transport)
FIGURE 3-9 The components of stream sediment load shown in terms of sediment source and mode of transport. (Reproduced from Hicks and Gomez 2003.)
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Geomorphology
Effect of discharge on sediment transport
• stream capacity = total load of sediment the stream can carry
FIGURE 3-10 The relationship between frequency and magnitude of discharge events responsible tor sediment transport: (a) suspended load, (b) bcdload. Curve 1 depiets the increase in sediment transport rate with increasing magnitude of discharge, and curve 2 describes the frequency of discharge events of a given magnitude Their product (dashed line) is the discharge that transports the most sediment, referred to as (>tl, the dominant or effective discharge. Qd is approximately Qbkt for suspended sediments, and is in the range Qi^ QUi tor bedltrad. (Reproduced from Richards 1982.)
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Abiotic Environment
Abiotic environment: Current
• boundary layer theory (Davis 1986, Vogel 1994)
• laminar (viscous) sublayer
3^ 0<-> y\\ ) O
Turbulent region
^- Buffer layer
\ Viscous ^ sublayer
Wot to Scate
i«- Transition
Turbulent
Water surface
Outer layer
Logarithmic layer
Roughness layer
FIGURE 5.3 Subdivision of hydraulicafly rough open-channel How into horizontal layers. Flow velocities within the "roughness layer" are unpredictable based solely on knowledge of flow in the logarithmic layer. This figure is not drawn to scale. (Reproduced from Hart and Finelli 1999.)
0.02 <D 0.013 ^ O01G 0.014 O01 2 0.01
o ta
C
o \-
as
T3 C
o m
0.008 0.0OB 0.004 0.002
Boundary Layer
Thickness at 1 meter/second
-
Currsrt velocity < o.s m/s
IL
0     0.1     0.2    0.3    0.4    0.5    0.S    0.7    0.0 0.9
Length Along Object (meters)
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Abiotic Environment
Laminar
Turbulent
Hydraulic variables
Reynolds number
Re = U D/r
Froude numher
Fr = U(gD)
-OS
Re < 500 —► laminar flow 500 < Re < 103 - 104 transitional flow
Re > I03    104 -» turbulent flow
Fr < 1 —► sutxritical flow
Fr = 1 —► eritieal flow
Fr > 1 —► super-critical flow
r 0
Mean vdOCity Water depth
Acceleration due to gravity Kinematic viscosity
cm s cm
l
Measured at OA depth from bottom or from open-channel Total depth, surface to bed
9,8 ms"2
1.004 x 10 (> m2 s 1 at 20 C
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Abiotic Environment
Influence of substrate roughness on the
stream flow
• low relative height of roughness elements to channel depth -> very komplex turbulent flow
• the role of wood and vegetation
FIGURE 5.7 Conceptualization of three types of flow occurring over a rough surface, depending upon differences in relative roughness and longitudinal spacing between roughness elements, (a) Isolated roughness flow, (h) wake interference How; (c) quasi-smooth flow. (Reproduced from Davis and Barmuta 1989, after Chow 1981.)
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Abiotic Environment
Hydraulic variables II
Boundary Reynolds number
Re * < 5 —► hydraulieally smooth flow 5 < Re* < 70 -> transitional flow Re* > 70 —► hydraulieally rough flow
Re * = rr*/i>
Shear velocity em s
Substrate roughness em
-i
FIGURE 5.6 Relationship between roughness Reynolds number and (a) number of invertebrate taxa and (b) macroinvcrtcbrate abundance in sampled areas of 0.07 m2 within three riffles in the Kangaroo River, New South Wales, Australia. Dotted lines indicate 95% confidence intervals. (Reproduced In mi Brooks ct al. 2005.)
0     500   1000 1500 2000 2500 3000  3500 4000
(a) Roughness Reynolds number
2.6 _ 24 22 2.0 1.8 1.6 1.4 12 1.0 0.8 0.6 0.4 0.2 0.0
+
o cn
o
a
c
05
"O
c
D
n <
±
_L
J
(b)
500    1000  1500  2000  2500  3000   3500 4000
Roughness Reynolds number
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Abiotic Environment
Near-bottom flow conditions
• very variable
• FST - hemisphere method
Statzner B. & Müller R. (1989) : Standard hemispheres as indicators of flow characteristics in
JVC Spirit Irrt
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Abiotic Environment
Adaptations of biota to current
Baetidae Heptagenidae f
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26
Abiotic Environment
Adaptations of biota to current II
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Abiotic Environment
Response of biota to current
Plectrocnemia conspersa (Polycentropodidae): v ~ 0-20 cm/s Hydropsyche instabilis (Hydropsychidae): v ~ 15-100 cm/s
Edington (1968)
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Abiotic Environment
Infuence of current on biota
• drag cost, dislocation
• increases food, nutrient and gas supply
• increases difusion rate on microbe membranes
• active and passive colonization: drift, refugee (debris dams, zones of transition, channel edges, hyporheic zone)
Ecological processes affected by flow
Dispersal
• Entrainment
• In-stream transport
• Settlement
Predator-prey interactions
• Encounter probability
• Escape tactics
Competition
• Exploitation
• Interference
• Spacing
i
+■    Benthic 4 organism
/ \
Habitat use
• Habitat structure
• Disturbance regime
Resource acquisition
• Resource distribution
• Capture efficiency
• Drag costs
FIGURE 5.2 Multiple causal pathways by which flow can affect organisms. Potential interactions among pathways are not shown. (Reproduced from Hart and Finelli 1999.)
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Abiotic Environment
Temperature
• influences physic-chemical processes
• influences biological processes - methabolic rate, distribution of organisms along river's length and in different geographic regions, leaf breakdown, nutrient uptake, production
• seasonal variation
Amazon river ~ 29+1 °C
temperate streams: 0-25 °C
high altitude and latitude: max. ~ 15°C
• cumulative temperature
7000
6000
CO
-g 5000 a? 4000
T3 TO
I 3000
2000
L
30      32     34      36     38     40 42
Latitude
44
46 48
FIGURE 5.11 Total annual degree-day accumulation (>() Q as a function of latitude for various rivers of the eastern United States. (Reproduced from Vannote and Sweeney 1980.)
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Abiotic Environment
Variability in water temperature
• at the source - T close to that one of groundwater
• max. diel variability in wide but shallow rivers (~ 4th order)
• spatial variability
o
o
<D i—
3
05 i—
<D
CL
£
4-1 —
P3
Mean daily water temperature
Wide and shallow rivers
Diel variability
Close to groundwater temperature at the source ^
Small streams
Large rivers
Downstream direction / stream order
Fig. 2 Mean daily and diel variability of water temperatures as a function of stream order/downstream direction.
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Abiotic Environment
The effect of impoundment on water
temperature
• increase residence time and surface area exposed to solar radiation
• surface-released dams
• deep bottom-released dams
FIGURE 5.13 Average monthly water temperatures in the Grand (canyon of the lower Colorado River before and utter the construction of Glen Canyon Dam, and tor a potential temperature management scenario using a temperature control device (TCD). Temperature data are from the t'S Cieological Survey at river mile 61 near the-confluence with the Little Colorado River. (Reproduced from Petersen and Paukcrt 2005.)
Month
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Abiotic Environment
Temperature requirements of organisms
• stenothermal vs. eurythermal
• cold-water fishes - max. 25°C
• warm-water fishes - Esocidae, Cyprinidae - max. ~ 30 °C
• specialized taxa - desert fish (up to 40°C), some invertebrates (up to 50°C), some Cyanobacteria (up to 75°C)
• importance of phylogenetic origin - Plecoptera (Hynes 1988), Odonata (Corbet 1980)
• cue, regulation and synchronization of insect life cycles - food availability and competition vs. predation risk
• high altitudes - short period of fast growth, long periods of dormance
• higher temperature -> smaller adults -> smaller fecundity
• temperature optimum - max. fecundity
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Abiotic Environment
1.0
CD ■4—<
CO
1
2
CD
Q
0.8 -
TO
b) E
g 0.6 -
0.4 -
0.2 -
0
Polypedilum spp.
8 16 24
Temperature (°C)
10 r-
lldl'Ki: 5 IK Daily growth rates < nig nig 1 day-1) as a function of temperature tor three aquatic insects found on snag habitat in the Ogeechee River Georgia, and reared in stream-side artificial channels. Insects include the midge Polyfwdihini, the black fly Simtdium, and the mayfly Baetis. (Reproduced from Benke 1993 )
e
</>
IS)
E
Q
u 1
001
J_I_I_I_I_L
ASONDJ FMAMJJ Months
FIGURE 51-1 Lirval growth period tor five species of riffle-inhabiting ephcmerellid mayflies in White Clay Creek, Pennsylvania. (•) Epbetnerella subittna, (A) E. damtbea; (□) SeratelUi deficiens; (■) S. serrata; (inverted open triangle) Euryophella verisimilis. (Reproduced from Sweeney and Vannote 1981.)
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Abiotic Environment
Factors influencing water temperature in streams
Topography
upland shading riparian vegetation geology (bedrock) aspect (stream orientation) latitude / altitude
Atmospheric conditions
solar radiation air temperature wind speed / humidity precipitation (rain / snow) evaporation / condensation phase change (e.g., melting)
Streambed
Conduction (sediment) hyporheic exchange groundwater input
friction (streambed) volume of water slope / water falls turbulence inflow / outflow
(Caissie 2006, Freshwat Biol.)
Stream discharge
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Primary production
Primary producers
benthic algae, vascular plants, bacteria, protists
macrophytes - angiosperms, bryophytes (mosses, liverworts), filamentous growth forms of algae
periphyton, phytoplankton
epilithon
Gathering, shredding and piercing
epipelon epipsammon epixylon epiphyton
Scraping and gathering
Rasping and scraping
Crustose
Stalked or short
Prostrate filamentous
ilamentous
FIGURE 6.1 Hypothetical representations of major growth forms of periphyton assemblages. Different modes of herbivory are expected to be most effective with particular growth forms. (Reproduced from Steinman 1996.)
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Primary production
Benthic algae
TABLE 6.1 Representation of major peri phy ton taxa in collections where all habitats were sampled, and from studies emphasizing epipelic and epiphytic assemblages. Patrick's (1961) data are from one time of year and include only those species represented by a minimum of six specimens in a very large sample (a count of 8,(X)() individuals) Inclusion of rarer species would at least double the species list. The studies of Moore (1972) and Chudyba (1965, 1968) probably represent close to the entire flora ibr the site.
.Xiunber of ta.xa
		All habitats		Efripelon	Efrif)byton
Diatoms	81a	80b	59c	321d	176c
Chlorophyta (green algae)	12	12		32	27
Cyanobactcria (blue-green algae)	9	9	6	14	19
Euglenophyta (phytoflagellatcs)	17	15	-	29	_r
Chrysophyta (yellow-brown algae)	0	l	i	1	2
Rhodophyta (red algae)	I	3	0	0	1
Total	120	120	80	388	225
a Potomac River, Maryland b Savannah River, (ieorgia
c White Clay Creek, Pennsylvania (Patrick 1961)
d Clay and detritus bottom stream, southern Ontario (Moore 1972)
c Epiphytes on Cladoplmraglomerata in the Skawa River, Poland (Chudyba 1965)
f Flagellates present but not identified to species
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Primary production
Primary production
gross vs. net promary production
biomass accrual per time for macrophytes "
small autotrophs - open stream gas exchange, light and dark bottle (chamber) exposure, radiotracer uptake
max. 1-6 g C m"2d_1
in shaded stream of temperate zone - 0.01-0.1gCm-2d4
after elimination of grazers, biomass significanly increases
scour, export and burial
release of DOC
Biomass Accrual
Resources -
Nutrients c Light : Temperature c
Biomass Loss
High Biomass
tow growing, tighty adhering taxa
Low Biomass
Disturbance
□ Substratum instability
□ Velocity
□ Suspended solids - Grazing -
□ Invertebrates
□ Fish
FIGURE 6.2 Factors controlling the biomass and physical structure of pcriphyton in streams. (Reproduced from Biggs 1996.)
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Primary production
Influence of light and seasonal variation
• high light - filamentous algae
• low light - diatoms, cyanobacteria
• limiting factor in small streams in forested areas
• seasonal variation
• studies: shaded vs. unshaded sites, effects of experimental clear-cutting
• masking effect of herbivory or limiting concentrations of nutrients
Light intensity
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Primary production
Influence of nutrients
• limiting factors generally in freshwaters: 1) P - 2) N:P < 16:1 (10-30:1) -> N becomes limiting, 3) Si and trace metals
• constant supply of nutients in running waters - relative ^physiological enrichment"
• thickness of periphyton mats
• colimitation by N+P
FIGURE 6.6 Changes in the numbers of the dominant diatom species in troughs enriched with NO3-N, PG»4-P, or both in combination. Troughs were placed in Carnation Greek, Vancouver Island, allowed -4 weeks to colonize, and then fertilized for 52 days. Note that periphyton populations peaked alter 30-40 days, and then declined sharply prior to termination of the fertilization experiment. (Reproduced from Stockner and Short reed 1978.)
5 D
4 5
I   I Others [   I Diatoma hiemale Fragil aria vaucheriae Achnanthes minutissima
20        30 40
Time (days)
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Primary production
Influence of flow
• high streamflow - scouring and abrasion
• different community composition in different flow conditions (diatoms, Cladophora)
• different growth form in different flow conditions
0)
>
o 0 Efl
o
100r 80 60 40 20
-• • •
_L
200      400     600 800
Stone size (I x w, cm2)
1000
FIGURE 6.12 Amount of stone surface covered by the moss Hygrofjyptmm as a function of stone size in a mountain stream. (Reproduced from McAuliffe 1983.)
1000 0 r
o
sz O
100.0 -
E
CT) CT3
=     10.0 -
JZ Q. O
FIGURE 6.11 Chlorophyll a responses to variation in water column velocities (If) in long filamentous green algal communities in the Waiau River, New Zealand. (Reproduced from Biggs ct al. 1998.)
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Primary production
Phytoplankton
•  pOtamoplanktOn, displaced Cells Temperature CO Temperature (X)
from benthos, backwaters and impoundments
• diatoms, cyanobacteria, Chlorophycae
• large lowland rivers, slow water current
• export up to hundreds km
• residence: tens of days
• 1-2 doubling per day
FIGURE 6.15 Schematic diagram comparing effect of depth of mixing on primary production in phytoplankton of a lake versus a river. In a lake (a), establishment of a temperature barrier between surface and deep waters restricts mixing to uie upper few meters. In a river (b), temperature stratification is impeded by turbulence of flow, and the water column typically mixes from top to bottom. Depths of 5-20 m are common in large rivers. Rivers often carry substantial sediment loads, restricting light penetration to, at best, the upper 1-2 m.
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Decomposition
Heterotrophic energy sources
• allochtonous sources usually dominate the photosynthetic ones
• mineralization, storage or export
Detrital energy sources
TABLE 7.1 Sources or organic matter (OM) to fluvial ecosystems.
Sources of input
Comments
Coarse particulate organic matter ((TOM)
• Leaves and needles
• Macrophytes during dichack*
• Woody debris
• Other plant parts (flowers, fruit, pollen)
• Other animal parts (feces and carcasses )
Major input in woodland streams, typically pulsed seasonally Locally important
May be major biomass component, very slowly utilized Little information available Little information available
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Decomposition
Leaf breakdown
• the loss of leaf mass is loglinear
• Wt= Wj x e"kt (Webster & Benfield 1986) Wt... dry mass at time t
Wj... initial dry mass
k (days-1)... measure of breakdown rate
• breakdown rate depends on tempetarure, N availability, pH, hydrological regime
• autumn-shed, the loss in april is ca 85%
0 2 4 6 8
Time (week)
FIGURE 7.1 Leaf dry mass remaining (as %) from alder ( # ) and willow (O) Icral' packs in an experiment conducted in a Black Forest stream, Germany. Error bars represent 95% confidence Intervals. (Reproduced from Hither and Ciessner 2002.)
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Decomposition
Braked own rate
high N concentration - fast breakdown lignin and celulose - slow breakdown
>
o
20
50
Half-life (days) 100
200
T
> Hydrocharitaceae (6)
♦        Gentianaceae (10) Nymphaeaceae {16)
-•-       Najadaceae (14)
♦- Pontederiaceae (3)
♦- Podoslemaceae (3)
Typhaceae (14) -•-
Poaceae (20) Polypodiaceae (5) ■
Cyperaceae (26) • Juncaceae (5) -•-
0.0500 0.0250 0.0100 O.OOSO
Breakdown rate (day1)
0.0025
500 -
_L
0.0010
20 I
50
I
Half-life (days) 100
200
500
—r—
Magnoliaceae (3)
- Comaceae(l6) ♦       Oleaceae (8)
Belulaceae (35) — Salicaceae (33) ■ Ulmaceae (10) — Taxodiaceae (4)-
Aceraceae (73) -
Myrtaceae (7) -
Juglandaceae (23)
Platanaceae (14)
Fagaceae (105) Ericaceae (16) -
-L
Pinaceae (38)
-L
0.0500
0.0250
0.0100
0.0050
0.0025
0.0010
.1__J______^1-   /-J-___— 1 A
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Decomposition
Leaf breakdown
Leaf processing sequence
Leaf fall and blow in
Microbial colonization physical 9n3 en and softening -*V
Process
Leaching of soluble
components to DOM
Amount of weight loss
5-25%
Mineralization by microbial respiration toC02
5%
Invertebrate colonization continued microbial activity and breakdown
Conversion to
FPOM
Increasing protein content
Further microbial conversion
20-35%
Feces and fragments
15-25%
-30%
10
100
250
Time (days)
FIGURE 7.3 The processing or ""conditioning sequence tor a medium-fast deciduous tree leal in a temperate stream. Leached DOM is thought to he rapidly transferred into hiofilms by microbial uptake.
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Decomposition
Microbial decomposition
• aquatic hyphomycetes dominate during 12-18 weeks, up to 30 species, only 2 dominant, nearly no succession
• bacteria dominate terminal stage
• synergic and antagonistic interaction
other macroinvertebrates shredders    I    I fungi
bacteria
FIGURE 7.6 Proportions of biomass of bacteria, fungi, shredders, and other macroinvertebrates during alder ind willow leaf decomposition in a Black Forest stream, CTcrmany. (Rcpn)dueed from Hieber and Gcssncr 2002.)
4 6 Time (week)
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Decomposition
Invertebrate shredders
• aquatic insects (e.g., Tipula) and crustaceans
• detritovores significantly accelerate decomposition
1 10 100
W        Shredder biomass (mg g 1 AFDM)
FIGURE 7.10 Correlations between leaf breakdown rates and (a) denialy and (b) biomass of shredders exprcs?>cd per ^ram of leaf AFDM. (Reproduced from Sponsetler and Benficld 2001.)
(b)
2 4 6
Time (week)
FIGURE 7.9 Colonization of alder (#) and willow (O) leal pucks by (u) macrt)invurtubratu!i and (b) shredders in a Black Forest stream, Germany. Error bars represent 95% confidence intervals. (Reproduced from Hieber and (iessner 2(X)2.)
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