International audienceThe semi-alluvial rivers of the Gaspé Peninsula, Québec (Canada), recruit and transport vast quantities of large wood. The rapid rate of channel shifting due to high-energy flows and non-cohesive banks allows the recruitment of large quantities of wood that in turn greatly influence river dynamics. The delta of the Saint-Jean River has accumulated a flux of wood since 1960, creating frequent avulsions, and now has a wood raft of more than 3 km in length. The Raft of the Saint-Jean River on the Gaspé Peninsula, Québec, Canada is an exceptional amount of wood that is unusual but natural. The river has complex large-wood dynamics that promote the formation of large wood jams in the river delta. The jam configuration allows a unique opportunity to apply a wood budget at the scale of a long river corridor and to better understand dynamics of large wood in river. A wood budget includes the evaluation of wood volumes (i) produced by bank erosion (input), (ii) still in transit in the river corridor (deposited on bars or channel edges), and (iii) accumulated in the delta (output). The budget is based on an analysis of aerial photos dating back to 1963 as well as surveys carried out between 2010 and 2014, all of which were used to locate and describe large wood accumulations along a 60 km river section. Understanding the interannual large wood dynamics in the Saint-Jean River can assist river managers determine sustainable solutions for the issue of wood rafts

Boivin, Maxime

Buffin-Bélanger, Thomas

Piégay, Hervé

Name not available

Implementation and validation of large wood analysis for wood budgeting in a semi-alluvial river

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*Maxime Boivin 1, 2,3; Thomas Buffin-Bélanger1,3 and Hervé Piégay2   1 Département de Biologie, Chimie et Géographie. Université du Québec à Rimouski.  2 UMR5600 EVS / ENS-Lyon. 3 CENTRE FOR NORTHERN STUDIES (CEN) / EnviroNord / BORÉAS  maxime.boivin@uqar.ca  Implementation and validation of large wood analysis for wood budgeting in a semi-alluvial river Flow direction Saint-Jean River  48°46'17.33"N and  64°26'27.55"O -Watershed aera : 1134 km2 -Length of river: 130 km Case of the St-Jean River, Gaspé, Québec  However, the rafts are  a source of  : - conflicts between users and managers  - financial stress  due to decreasing fishing trips Case of the St-Jean River, Gaspé, Québec  Majestic river : 1000$ / day for salmon fishing;  4 million $ in economic benefits for the region;  Study site river for salmon and eel habitat;  1960 : emerging of large wood rafts in the delta;  2015 : 3 gigantic rafts;   The Rafts has an exceptional amount of wood, unusual but natural; (Boivin et al. 2015, Geomorphology) The Rafts: 1963-2013 GeoEye-1 Satellite Imagery, 2012 1.  Systematic interannual input in the delta since 1963; There is a need to develop management tools and strategies to deal with large wood in medium to large rivers and in rivers of cold areas. 2. Important variability in annual wood input in the delta; Boivin et al. (2015) Objectives The overall study aims to develop a LW budget from the analysis of the dynamics of large wood in a semi-alluvial river in a cold region.   Here, the analysis will focus on 3 keys questions pertaining to the wood budget:   1. Where and when does wood recruitment occur within the fluvial corridor for the period 1963-2013 2. Where and when does wood accumulation occur within the fluvial corridor in relation to geomorphic variables for the period 2010-2013; 3. What is the interannual variability of large wood transport in relation to hydrologic variables; Methodology 3) Hydrogeomorphological data  Aerial photos and satellite imagery to characterise the geomorphological trajectory   Field campaigns to define river units and morhologies 1) Wood in space and time  Aerial photos and satellite imagery to infer wood recrutment and wood accumulation volumes   Field campaigns to locate and to quantify wood volume within the river   In situ video cameras to estimate wood discharges and wood transport dynamics   2) Hydrometeorological data   River discharge   Precipitation   1) Lateral migration and avulsion processes are observed at many locations whereas landslide scars were not observed within the entire river corridor. As a result, wood recruitment results mostly from lateral migration and avulsion on the forested floodplain. 2) Standing wood volume on the floodplain was estimated at 25 locations (*) providing values ranging between 0,02m³ and 0,07m³ per m². The wood recruitment volumes were estimated from the product of wood density by the eroded surface of the floodplain.  * * Results  1. Recruitment dynamics : 1963-2013 Wood delivery from floodplain (m³)  1963-1993 : 17 700 m³ ± 262m³ Wood delivery from floodplain (m³)  2004-2013 :  17 000 m³ ± 251m³ ± 590 m³ ± 8,7m³ / year 1860 m³ ± 28m³ / year Wood delivery from floodplain (m³)  1993-2004 :  6 900m³ ± 102m³  630 m³ ± 9,3m³ / year Results  1. Wood recruitment dynamics : 1963-2013 Major ice break up Hydrometeorological events 2 types of transport of large wood in northern environments Results  2. Wood accumulation dynamics : 2010-2013 13968462642301002003004005006007008002010 2011 2012 2013Number of logsLW94289 3213426389 79 771421 242711010010002010 2011 2012 2013Number of accumulationYear Total LWJLWJ > 100 m³LWJ > 1000 m³• Increase in the overall wood volume between 2010 and 2013 :    225%  • Significantly increasing between 2010 and 2011 :     207%   • Significantly increasing LWJ larger than 100m3 and for LWJ larger than 1,000 m3;  • Significant increase of LW between 2010 and 2011 :    392%   • Slow decrease until 2013  Large wood jams (LWJ) Individual large wood (LW) A. Interannual characteristics of large wood (2010-2013)  Results  2. Wood accumulation dynamics : 2010-2013 • Width, height, wood volume/LWJ, surface area/LWJ and density index have changed significantly between 2010 and 2011-2012-2013; (Anova and Scheffe’s test : P < 0.01 (n: 1040)) • Characteristics are substantially similar between 2011, 2012 and 2013.  B. Interannual characteristics of large wood (2010-2013)  Asterisk (*) shows the variables with a significant change and the arrow shows the direction of change.  Results  2. Wood accumulation dynamics : 2010-2013 Length (m) Width (m) height (m) Volume (m³)/LWJ  0200040006000800010000120001400016000Erosion rate /km (m2/km)Distance from delta (km) Erosion rate per km (1963-2004)Erosion rate per km (2004-2013)0100020003000400050006000700080009000Air-wood volume (m2/km)Distance form delta (km)2010201120122013Accumulation zone Pre-delta (Unit A) +199%Transit Semi-alluvial zone (Unit B)Wood production and retention zone (Unit C) +30%+269%+43%Volume : m³ x101Four large units and six reaches are observed in the river corridor, upstream from the delta :    A. The semi-alluvial and alluvial units are the zones with large accumulation of LW (0-9km);    B.   The semi-alluvial units (10-29km), have lower accumulation and are the transit zone;   C.   The upstream alluvial unit (30-60 km), shows the maximum retention and production of  LW C. Mobility and retention of large wood (2010-2013)  Results  2. Wood accumulation dynamics : 2010-2013 A B C Delta raft 3. Hydro-geomorphological analysis : 1963-2013 A. Longitudinal distribution of large wood and geomorphology characteristics y = 15838x - 17119R² = 0,360100020003000400050001,05 1,1 1,15 1,2 1,25 1,3Wood volume (m³)/kmSinuosity rate Confined section (semi-alluvial)y = 0,0147x - 186,64R² = 0,7605001000150020002500300035000 50000 100000 150000 200000 250000Wood Volume (m³)/kmSum of bar surface aera (m2)/kmy = -3,7702x + 6613,9R² = 0,750100020003000400050000 500 1000 1500 2000Wood Volume (m³)/kmSum of unit stream power (ω/m2)264531264531264 531• Relationships is strong between sinuosity, bar surface area and decrease with unit stream power.  • Two sections have the highest contributions to wood recruitment via bank erosion and avulsion (Unit A and Unit C). These sections play a key role in the temporary storage of wood in transit and  a large amount remains temporarily stored on bars. Confined section (semi-alluvial) 3. Hydro-geomorphological analysis : 1963-2013 B. Extreme event and ice cover dynamics   adapted from Bernatchez et al., 2008 Increase in total precipitation (snow and rain)  ± 120mm in last 30 years. Extreme rain events (i.e: huricane) and the intensity increases in last 30 years.  Large wood transport threshold without ice ± 130 m³/s Large wood transport threshold with ice break-up during winter ± 40 m³/s Critical flow for wood mobility  Centennial flood centennial flood in 2010  Major ice break-up in 2012   • Extreme hydrometeorological events in december 2010 and major ice break up in March 2012 are the cause for large production and retention of LW.   • Wood discharge is not simply linked to flood intensity in cold rivers due to LW transport during ice breakup;  • Wood discharge is influenced by previous events (where is the wood in active channel and availability of LW)  • Wood production due to channel migration is increasing in period 2004-2013 compare with period 1963-1993 and 1993-2004 .   • Extreme events in Eastern Canada are increasing with the number of Post-tropical storms  Discussion What are the links and interelations between flow, sediments and wood discharges?  1) Changes in hydro-geomorphological characteristics influence wood recruitments  Increasing wood discharge = Discussion Influence of ice cover in wood discharge.   2) Presence of recurrent Ice-jams and major Ice Break-up influence wood accumulation dynamics and interannual variability of transport Managers of the river have removed more than 1200 meters of the large raft in the south channel during 2015 winter.  Discussion Management decision : research opportunity Residence time by dendrochronology : ± 400 samples on 1500 meter Large raft long Conclusion • Regional conditions in semi-alluvial river and in northern environment play a key role; • Actually, the volumes available in the watershed are enormous   • The majority of the wood is produced by the natural lateral migration  • High capacity on wood retention in semi-alluvial river in Quebec   • Ice cover dynamics play key role;  • Critical flow for wood transport without ice: 130m³ / s • Critical flow for wood transport with ice : 40 m³ / s  • More retention of wood in river corridor  • More lateral erosion = more wood in transit  • Significant increase between  2004 and 2013  • Flood flow is not the only one factor to explain volume of large wood in cold river.  Fluvial geomorphology research group (LGDF-UQAR) Thank you to Véronic Parent, Claude-André Cloutier, Sylvio Demers, Dany Lechasseur, J-P Marchand, Taylor Olsen, Patrick Bouchard, Pierre Simard , Volodia  and Simon Claveau for assistance in the field Thank you for your attention! Residence time by dendrochronology : ± 400 samples on 1500 meter Large raft long To be continued Discussion Missing data for large wood budget 

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Implementation and validation of large wood analysis for wood budgeting in a semi-alluvial river

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