3.1. Potential for Hybrid Poplar Riparian Buffers to Provide Ecosystem Services at the Watershed Scale
For the three studied watersheds, the potential for ecosystem service provision varies greatly for each km of stream where hybrid poplar buffers could replace non-managed herbaceous buffers (
Table 6). This trend is related to the assumed difference in agricultural riparian zone fertility (productivity) that likely exists between the three watersheds. For each stream km where poplar buffers would be implemented, greater ecosystem service provision potential is expected in the Pike River watershed, where annual row crops are the dominant form of agriculture (
Table 1), followed by the Eaton River and Magog River watersheds, where perennial crops and pasture are the dominant forms of agriculture (
Table 4).
While ecosystem services per stream km are expected to be higher in the Pike River watershed (
Table 6), this watershed has also the greatest proportion and length of streams bordered by agricultural land use, with 439 km of streams, representing 56% of total stream length for the entire watershed (
Table 2). This situation strongly contrasts with the Magog River and Eaton River watersheds, where 115 km and 183 km of streams are bordered by agricultural land use, which respectively represent 14% and 17% of total stream length in these watersheds. Consequently, despite its smaller size in terms of watershed area (
Table 1), there is a much greater ecosystem service provision potential in the Pike River watershed nine years following the replacement of herbaceous buffers by hybrid poplar buffers (
Table 7).
Table 6.
Potential ecosystem service provision after 9 years following the replacement of non-managed herbaceous buffers by hybrid poplar buffers along 1 km of stream in three watersheds with contrasted soil fertility. The biomass produced along streams could be used to heat farmhouses instead of fuelwood harvested in natural woodlots, allowing an opportunity for conservation. Alternatively, poplar biomass could be used to heat greenhouses and contribute to displace fossil fuel use.
Table 6.
Potential ecosystem service provision after 9 years following the replacement of non-managed herbaceous buffers by hybrid poplar buffers along 1 km of stream in three watersheds with contrasted soil fertility. The biomass produced along streams could be used to heat farmhouses instead of fuelwood harvested in natural woodlots, allowing an opportunity for conservation. Alternatively, poplar biomass could be used to heat greenhouses and contribute to displace fossil fuel use.
Watershed (Paired Site/Fertility Class) 1 | Buffer Area (ha/km) | Wood Volume (m3/km) 2 | Biomass (t/km) 2 | Biomass Storage Increase | Home Heating (Houses/km) 3,4 | Greenhouse 3,4 | |
---|
Woody | Stem | C (t/km) | N (t/km) | P (t/km) | New | Old | Heating (ha/km) | Fuel Oil Displaced (L/km) | Forest Conservation (ha/km) |
---|
Magog River (Magog/low) | 0.9 | 104 | 46 | 34 | 26.1 | 0.26 | 0.03 | 0.48 | 0.35 | 0.004 | 17,795 | 2.6 |
Eaton River (St-Isidore/moderate) | 0.9 | 249 | 108 | 80 | 56.6 | 0.57 | 0.05 | 1.12 | 0.82 | 0.009 | 41,600 | 6.1 |
Pike River (Brompton/high) | 0.9 | 405 | 173 | 128 | 96.0 | 1.01 | 0.13 | 1.81 | 1.31 | 0.015 | 66,985 | 10.4 |
Table 7.
Potential ecosystem service provision after 9 years following the replacement of 100%, 25% or 10% of non-managed herbaceous buffers by hybrid poplar buffers along perennial and intermittent streams of the three studied watersheds.
Table 7.
Potential ecosystem service provision after 9 years following the replacement of 100%, 25% or 10% of non-managed herbaceous buffers by hybrid poplar buffers along perennial and intermittent streams of the three studied watersheds.
Buffer Scenarios | Watershed and Stream Type | Stream Length (km) | Buffer Area (ha) | Wood Volume (m3) | Woody Biomass (t) | Biomass Storage Increase | Houses Heated 1 | Greenhouses 1 | |
---|
Whole Tree | Stem Wood | C (t) | N (t) | P(t) | New | Old | Heat Energy (ha GH) | Fuel Oil Displaced (L) | Forest Conservation (ha) |
---|
100% | Perennial | | | | | | | | | | | | | |
| Magog River | 50 | 45 | 5221 | 2312 | 1702 | 1307 | 13 | 1.3 | 24 | 18 | 0.20 | 892,761 | 131 |
| Eaton River | 64 | 58 | 15,998 | 6923 | 5112 | 3636 | 36 | 3.0 | 72 | 53 | 0.59 | 2,672,804 | 394 |
| Pike River | 103 | 93 | 41,720 | 17,890 | 13,188 | 9898 | 104 | 13.1 | 186 | 136 | 1.54 | 6,907,519 | 1070 |
| Intermittent | | | | | | | | | | | | | |
| Magog River | 64 | 58 | 6701 | 2968 | 2185 | 1677 | 16 | 1.7 | 31 | 22 | 0.25 | 1,145,802 | 169 |
| Eaton River | 118 | 106 | 29,453 | 12,745 | 9411 | 6694 | 67 | 5.5 | 133 | 97 | 1.09 | 4,920,871 | 726 |
| Pike River | 336 | 302 | 135,862 | 58,260 | 42,947 | 32,233 | 338 | 42.5 | 607 | 442 | 5.00 | 22,494,317 | 3483 |
| All streams | | | | | | | | | | | | | |
| Magog River | 115 | 103 | 11,921 | 5280 | 3887 | 2984 | 29 | 3.0 | 55 | 40 | 0.45 | 2,038,563 | 300 |
| Eaton River | 183 | 164 | 45 ,451 | 19,668 | 14,523 | 10,330 | 103 | 8.6 | 205 | 149 | 1.69 | 7,593,675 | 1121 |
| Pike River | 439 | 395 | 177,582 | 76,151 | 56,135 | 42,132 | 442 | 55.6 | 794 | 577 | 6.53 | 29,401,836 | 4553 |
25% | Perennial | | | | | | | | | | | | | |
| Magog River | 13 | 11.3 | 1305 | 578 | 426 | 327 | 3.2 | 0.3 | 6 | 4 | 0.05 | 223,190 | 33 |
| Eaton River | 16 | 14.5 | 3999 | 1731 | 1278 | 909 | 9.1 | 0.8 | 18 | 13 | 0.15 | 668,201 | 99 |
| Pike River | 26 | 23.2 | 10,430 | 4473 | 3297 | 2475 | 26.0 | 3.3 | 47 | 34 | 0.38 | 1,726,880 | 267 |
| Intermittent | | | | | | | | | | | | | |
| Magog River | 16 | 14.5 | 1675 | 742 | 546 | 419 | 4.1 | 0.4 | 8 | 6 | 0.06 | 286,450 | 42 |
| Eaton River | 30 | 26.6 | 7363 | 3186 | 2353 | 1674 | 16.7 | 1.4 | 33 | 24 | 0.27 | 1,230,218 | 182 |
| Pike River | 84 | 75.6 | 33,965 | 14565 | 10,737 | 8058 | 84.6 | 10.6 | 152 | 110 | 1.25 | 5,623,579 | 871 |
| All streams | | | | | | | | | | | | | |
| Magog River | 29 | 25.8 | 2980 | 1320 | 972 | 746 | 7 | 0.8 | 14 | 10 | 0.11 | 509,641 | 75 |
| Eaton River | 46 | 41.1 | 11,363 | 4917 | 3631 | 2582 | 26 | 2.1 | 51 | 37 | 0.42 | 1,898,419 | 280 |
| Pike River | 110 | 98.8 | 44,395 | 19,038 | 14,034 | 10,533 | 111 | 13.9 | 198 | 144 | 1.63 | 7,350,459 | 1138 |
10% | Perennial | | | | | | | | | | | | | |
| Magog River | 5 | 4.5 | 522 | 231 | 170 | 131 | 1.3 | 0.13 | 2.4 | 1.8 | 0.02 | 89,276 | 13 |
| Eaton River | 6 | 5.8 | 1600 | 692 | 511 | 364 | 3.6 | 0.30 | 7.2 | 5.3 | 0.06 | 267,280 | 39 |
| Pike River | 10 | 9.3 | 4172 | 1789 | 1319 | 990 | 10.4 | 1.31 | 18.6 | 13.6 | 0.15 | 690,752 | 107 |
| Intermittent | | | | | | | | | | | | | |
| Magog River | 6 | 5.8 | 670 | 297 | 218 | 168 | 1.6 | 0.17 | 3.1 | 2.2 | 0.03 | 114,580 | 17 |
| Eaton River | 12 | 10.6 | 2945 | 1275 | 941 | 669 | 6.7 | 0.55 | 13.3 | 9.7 | 0.11 | 492,087 | 73 |
| Pike River | 34 | 30.2 | 13,586 | 5826 | 4295 | 3223 | 33.8 | 4.25 | 60.7 | 44.2 | 0.50 | 2,249,432 | 348 |
| All streams | | | | | | | | | | | | | |
| Magog River | 11 | 10.3 | 1192 | 528 | 389 | 298 | 2.9 | 0.30 | 5.5 | 4.0 | 0.05 | 203,856 | 30 |
| Eaton River | 18 | 16.4 | 4545 | 1967 | 1452 | 1033 | 10.3 | 0.86 | 20.5 | 14.9 | 0.17 | 759,368 | 112 |
| Pike River | 44 | 39.5 | 17,758 | 7615 | 5613 | 4213 | 44.2 | 5.56 | 79.4 | 57.7 | 0.65 | 2,940,184 | 455 |
Over nine years, replacing all herbaceous buffers by hybrid poplar buffers along both perennial and intermittent streams (100% replacement scenario) would increase timber (or woody biomass) production by 11,921 m
3 (3887–5280 t), 45,541 m
3 (14,523–19,668 t) and 177,582 m
3 (56,135–76,151 t) in the Magog River, Eaton River and Pike River watersheds respectively (
Table 7). Because replacing non-managed herbaceous buffers by hybrid poplar buffers leads to significant gains in C, N and P storage in vegetation biomass [
35], increases in C and nutrient storage potential could reach 2984 t C, 29 t N and 3.0 t P in the Magog River watershed, 10,330 t C, 103 t N and 8.6 t P in the Eaton River watershed, and up to 42,132 t C, 442 t N and 55.6 t P in the Pike River Watershed, under the 100% replacement scenario (
Table 7). This increase in C storage in the Pike River watershed over nine years (42,132 t C) is approximately equivalent to the gas emissions of 32,500 average-sized passenger vehicles during one year (each travelling 18,000 km/year) [
79]. In the Pike River watershed, P losses from agricultural land have been estimated at 0.39 kg/ha/year for hayfields and pastures, and at 2.48 kg/ha/year for corn (
Zea mays) fields (or 3.51 kg/ha and 22.3 kg/ha over nine years) [
80]. Thus, an increase in biomass P storage of 55.6 t associated to poplar buffer implementation would be equivalent to P losses from 15,800 ha of hayfield or pasture, or from 2500 ha of cornfields over 9 years. Nitrogen losses from agricultural land have been established at 27 kg N/ha/year or 243 kg N/ha over 9 years in the nearby Beaurivage watershed (40% annual row crops, 60% pasture/hayfield) in southern Québec [
81]. Based on these values, increasing N storage by 442 t N with poplar buffers in the Pike River watershed would be equivalent to the N losses from 1800 ha of cultivated land over nine years.
The large-scale implementation of tree riparian buffers would be an excellent contribution to improving water quality and to rehabilitating stream habitats in southern Québec. All watersheds from this region have a high to very high conservation priority because they support diverse fish communities and very productive aquatic ecosystems, while being threatened by high levels of anthropogenic stressors [
82]. Environmental problems related to cyanobacterial blooms are of special concern in the Pike River watershed and in its receiving water body, the Missisquoi Bay of Lake Champlain. Phosphorus enrichment in this bay is a major factor contributing to cyanobacteria proliferation; a factor mostly related to agricultural activities in the watershed [
83]. More than a decade ago, cyanobacterial blooms and elevated cyanotoxin concentrations in the water led to public health warnings for swimming and for fish and water consumption from the lake, resulting in beach closings, but also in the desertion of local campgrounds and commercial sites [
84]. In summer 2015, cyanobacterial blooms in Missisquoi Bay still made the headlines of national news [
85], suggesting that issues of water pollution by excess nutrient inputs from cultivated land have not yet been resolved.
However, increasing nutrient storage in the vegetation biomass of poplar buffers may only have a partial effect on P exports from the Pike River watershed, as 82% of annual P discharges occur outside of the growing season, during spring snowmelt and spring or autumn rainfall events on bare agricultural soils [
83]. For agricultural non-point source pollution control, additional best management practices should be used to complement riparian buffer establishment. These could include building up soil health (no tillage or reduced tillage, crop rotation), in-field water control (upland filter strips, controlled drainage), and below-field water control (constructed wetlands) [
86]. A strategy which aims at establishing efficient riparian buffers for water quality protection should also consider variable width buffers and priority areas for placement, based on adjacent farmland cropping system, slope, soil type, pollutant to be trapped/transformed, and hydrological connectivity (concentrated flow path) between fields and streams [
87,
88,
89] (
Figure 2). Although fixed-width buffers are administratively simpler to manage [
90], they may have limited non-point source pollution control capacity in agricultural landscapes with non-uniform topographical features and/or cropping systems. To assist land planners in the establishment of more efficient water quality buffers on farmland with non-uniform runoff patterns, a GIS-based tool using a digital elevation model has recently been developed (the
AgBufferBuilder) [
91].
Establishing buffers on smaller (low order) and intermittent streams is very important, as headwater streams comprise more than 85% of the total length of stream networks, thus collecting most of the water and dissolved nutrients from adjacent terrestrial ecosystems [
92]. In all studied watersheds, intermittent farm streams without a forest cover accounted for more stream length than perennial farm streams without a forest cover (
Table 2), suggesting that these intermittent streams are major recipients of nutrient, pesticide and sediment pollution. Although not considered in this study, it would be very useful to map ephemeral streams, road side ditches, swales and surface field drainage ditches in agricultural watersheds, as they are key hydrological features that should also be considered for riparian buffer establishment [
93].
Figure 2.
Examples of concentrated flow paths in hybrid poplar buffers established along a crop field (
left) and along a pasture (
right) riparian zone in southern Québec. In these hot spots for sediment and nutrient transport, wider buffers and additional conservation practices (ex: stiff-stemmed filter strip, ephemeral stream fencing) would be needed to allow surface runoff dispersion/infiltration and improve the water quality function [
20].
Figure 2.
Examples of concentrated flow paths in hybrid poplar buffers established along a crop field (
left) and along a pasture (
right) riparian zone in southern Québec. In these hot spots for sediment and nutrient transport, wider buffers and additional conservation practices (ex: stiff-stemmed filter strip, ephemeral stream fencing) would be needed to allow surface runoff dispersion/infiltration and improve the water quality function [
20].
From an energetic perspective, the use of riparian buffers to produce biomass for bioenergy could be a significant contribution to the energyscape (
sensu Howard
et al. [
94]) of southern Québec. Planting hybrid poplars along the 439 km of farm streams in the Pike River watershed could provide 76,151 tons of whole-tree biomass (stems + branches) in less than a decade (
Table 7). This biomass could be chipped and used to heat 6.5 ha of greenhouses during nine years, which could displace 29.4 million litres of non-renewable fuel oil. Alternatively, the stem wood biomass produced (56,135 t) could be transformed into fuelwood that could be used locally to heat between 577 and 794 average-sized farmhouses for nine years (
Table 7).
A major indirect contribution to forest conservation at the watershed scale could also be achieved if fuelwood production in poplar buffers could replace fuelwood harvested in farm woodlots [
38]. This is because the stem wood biomass productivity of poplar buffers is about 3 to 12 times greater than natural forest productivity in the studied watersheds (
Table 4). Such differences in biomass productivity between upland forests and poplar riparian buffers are most likely related to greater availability of resources in linear agricultural riparian buffers (high nutrient, water and light availability), and the particularly high resource uptake rate and growth rate of hybrid poplars compared to native forest tree species [
39,
95]. Consequently, producing poplar fuelwood along 439 km of streams in the Pike River watershed, which represents a poplar buffer area of 395 ha, would be enough to compensate the fuelwood production loss associated with the conservation of 4553 ha of farm woodlots (
Table 7). This indirect potential contribution to forest conservation would be significant, as approximately 20,000 ha of forests are found in the Pike River watershed [
51]. Furthermore, a watershed scale implementation of poplar riparian buffers would rapidly increase forest connectivity at the landscape level, especially in the north-eastern part of the Pike River watershed, where many isolated forest fragments of various sizes are interconnected along the hydrological network (
Figure 1). Many of these forest fragments could be simply reconnected together by establishing tree corridors along both intermittent and perennial streams. Additionally, positive effects of poplar buffers on terrestrial biodiversity will likely be greater in the Pike River watershed because it has the lowest forest cover and the highest proportion of intensive agricultural land use (
Figure 1,
Table 1). This is because local allocation of habitat is far more important in oversimplified landscapes dominated by intensive agriculture than in more complex landscapes with a higher proportion of forest cover [
96]. Lastly, the indirect forest conservation opportunities created by large scale poplar buffer plantings would also create indirect C storage opportunities, as protected forests would have the chance to grow older, a process strongly linked with soil and biomass C accumulation in forest ecosystems [
97,
98].
At a projected width of 4.5 m (3 poplar rows), poplar riparian buffers cannot provide an optimal level of ecosystem services, and certainly not natural conditions typical of undisturbed riparian zones. Much wider riparian buffers will be needed to provide an optimal level of ecosystem services [
6,
9,
11,
16,
99]. However, wide buffers may be hard to implement watershed-wide, especially where intensive agriculture dominates, as a major disservice of tree buffer establishment is the loss of agricultural land. In the province of Québec, the current legislation allows land cultivation or livestock pasturing near streams, providing that a narrow vegetation buffer of 3 m be maintained [
100]. Consequently, increasing buffer width at 4.5 m, would require that a 1.5 m wide strip of agricultural land be converted into tree buffers along farm streams. In terms of area, planting 4.5 m wide poplar buffers along all non-forested farm streams would lead to an agricultural land loss of 34 ha in the Magog River watershed, of 55 ha in the Eaton River watershed, and of 132 ha in the Pike River watershed, representing between 0.5 and 1.1 % of total cultivated land depending on the watershed (
Table 8). Due to the very high agricultural land value in the Pike River watershed ($22,624/ha in 2014) [
101], the land value of 132 ha of agricultural land is approximately $3 million (
Table 8). In this same watershed, increasing buffer width to 10 m, as recommended by the provincial
Politique de protection des rives, du littoral et des plaines inondables [
100], would lead to an agricultural land loss of 615 ha, representing a value of nearly $14 million. As recently reviewed by Sweeney and Newbold [
11], forest buffers of 30 m or wider would be needed to maintain natural conditions in terms of water quality, habitat, and biotic features along the stream network. Extending buffer width to 30 m in the Pike river watershed would lead to a loss of 2370 ha of agricultural land, representing a value of more than $53 million (
Table 6). Such levels of land use conversion would seriously impinge on the food production service and would likely be socially unacceptable among the farming communities [
102]. In this context, landowners that implement wide riparian buffers should receive direct financial compensation for the loss of cultivated land, as many ecosystem services provided by riparian buffers have no market value for the moment. Presently, subsidies covering 70%–90% of buffer establishment costs are available [
103], but no compensation program for agricultural land loss exists for Québec farmers.
Table 8.
Potential loss of cultivated land following the implementation of hybrid poplar buffers of various width along all non-forested perennial and intermittent farm streams in the three studied watersheds. The value of the cultivated land that would be lost is also indicated (in Canadian $).
Table 8.
Potential loss of cultivated land following the implementation of hybrid poplar buffers of various width along all non-forested perennial and intermittent farm streams in the three studied watersheds. The value of the cultivated land that would be lost is also indicated (in Canadian $).
Buffer Width | Watershed and Stream Type | Stream Length (km) | Poplar Buffer Area (ha) | Legal Buffer Area (ha) 1 | Loss of Cultivated Land (ha) | Total Cultivated Land (ha) | Cultivated Land Lost (%) | Agricultural Land Value ($/ha) | Agricultural Land Value ($) |
---|
4.5 m | Perennial streams | | | | | | | | |
| Magog River | 50 | 45 | 30 | 15 | 3114 | 0.48 | 4040 | 60,806 |
| Eaton River | 64 | 58 | 39 | 19 | 8551 | 0.23 | 4040 | 77,871 |
| Pike River | 103 | 93 | 62 | 31 | 26,133 | 0.12 | 22,624 | 699,896 |
| Intermittent streams | | | | | | | | |
| Magog River | 64 | 58 | 39 | 19 | 3114 | 0.62 | 4040 | 78,041 |
| Eaton River | 118 | 106 | 71 | 35 | 8551 | 0.42 | 4040 | 143,367 |
| Pike River | 336 | 302 | 201 | 101 | 26,133 | 0.39 | 22,624 | 2,279,210 |
| All streams | | | | | | | | |
| Magog River | 115 | 103 | 69 | 34 | 3114 | 1.10 | 4040 | 138,847 |
| Eaton River | 183 | 164 | 110 | 55 | 8551 | 0.64 | 4040 | 221,238 |
| Pike River | 439 | 395 | 263 | 132 | 26,133 | 0.50 | 22,624 | 2,979,106 |
10 m | Perennial streams | | | | | | | | |
| Magog River | 50 | 100 | 30 | 70 | 3114 | 2.26 | 4040 | 283,762 |
| Eaton River | 64 | 129 | 39 | 90 | 8551 | 1.05 | 4040 | 363,398 |
| Pike River | 103 | 206 | 62 | 144 | 26,133 | 0.55 | 22,624 | 3,266,182 |
| Intermittent streams | | | | | | | | |
| Magog River | 64 | 129 | 39 | 90 | 3114 | 2.89 | 4040 | 364,190 |
| Eaton River | 118 | 237 | 71 | 166 | 8551 | 1.94 | 4040 | 669,048 |
| Pike River | 336 | 672 | 201 | 470 | 26,133 | 1.80 | 22,624 | 10,636,312 |
| All streams | | | | | | | | |
| Magog River | 115 | 229 | 69 | 160 | 3114 | 5.15 | 4040 | 647,951 |
| Eaton River | 183 | 365 | 110 | 256 | 8551 | 2.99 | 4040 | 1,032,446 |
| Pike River | 439 | 878 | 263 | 615 | 26,133 | 2.35 | 22,624 | 13,902,493 |
30 m | Perennial streams | | | | | | | | |
| Magog River | 50 | 301 | 30 | 271 | 3114 | 8.70 | 4040 | 1,094,509 |
| Eaton River | 64 | 386 | 39 | 347 | 8551 | 4.06 | 4040 | 1,401,678 |
| Pike River | 103 | 619 | 62 | 557 | 26,133 | 2.13 | 22,624 | 12,598,129 |
| Intermittent streams | | | | | | | | |
| Magog River | 64 | 386 | 39 | 348 | 3114 | 11.16 | 4040 | 1,404,732 |
| Eaton River | 118 | 710 | 71 | 639 | 8551 | 7.47 | 4040 | 2,580,615 |
| Pike River | 336 | 2015 | 201 | 1813 | 26,133 | 6.94 | 22,624 | 41,025,773 |
| All streams | | | | | | | | |
| Magog River | 115 | 687 | 69 | 619 | 3114 | 19.86 | 4040 | 2,499,241 |
| Eaton River | 183 | 1095 | 110 | 986 | 8551 | 11.53 | 4040 | 3,982,293 |
| Pike River | 439 | 2634 | 263 | 2370 | 26,133 | 9.07 | 22,624 | 53,623,903 |
The methodology used for extrapolating ecosystem services suggests that fertility variations between watersheds result in a large variation of hybrid poplar yield (per km of stream), further resulting in proportional variations in the heating energy produced, in potential for fossil fuel displacement or in forest area that could be set aside for conservation (
Table 6). Such variations in watershed productivity would also greatly affect the C and nutrient storage services of poplar buffers after nine years. These assumptions related to variations in ecosystem services across a regional gradient of fertility are supported by recent studies done in southern Québec [
35,
42,
104,
105]. Therefore, used as a sole predictor variable, the length of the stream network available for hybrid polar buffer implementation may not be a robust indicator of the ecosystem services provision potential abovementioned, unless site quality remains relatively constant across sites or watersheds. This highlights the need to collect data on biomass productivity and C and nutrient stocks across multiple riparian buffer sites in each of the studied watersheds in order to improve the robustness of projections about ecosystem service provision at the watershed scale.
In addition, our projections related to the creation of indirect forest conservation opportunities resulting from the replacement of fuelwood harvested in woodlots by hybrid poplar fuelwood harvested in riparian buffers contain a certain amount of uncertainty. We possibly underestimated such a service because the only available data on private forest productivity in the Estrie region (Magog and Eaton River watersheds) seems quite optimistic (3.2 m
3/ha/year) [
75], compared to forest productivity estimates on public forestland in the study area (1.5 m
3/ha/year in the Estrie region and at 1.6 m
3/ha/year in the Chaudière-Appalaches region) [
106].
Improving the design of riparian buffers could also result in greater ecosystem service provision per kilometer of stream planted with hybrid poplars. For example, as several services are directly and positively affected by biomass yield (
Table 6 and
Table 7), the selection of the most productive hybrid poplar genotypes could be a way to maximise productivity-related services [
41,
42]. However, this would require a good knowledge of the suitability of different genotypes across changing site conditions given the frequent Genotype × Environment interactions observed in hybrid poplar yield at the regional scale [
104,
107]. Otherwise, the use of generalist genotypes (
P. maximowiczii hybrids) could be a way to obtain good yields in variety of environments, including colder (higher elevation) sites [
105,
107,
108].
Improving the efficiency of residential heating systems could also be a way to achieve a higher amount of ecosystem services because energetic efficiency is proportionally related to the biomass requirement of a single farmhouse (
Table 9). Thus, the number of houses that could be heated with a fixed biomass quantity is very sensitive to changes in heating system efficiency (
Table 9). For example, under the 100% buffer scenario, the Pike river watershed could produce 56,135 t of wood logs (
Table 7), a biomass supply that could heat 381–524 houses equipped with a low efficiency (40%) woodstove or 857–1178 houses equipped with a very efficient (90%) masonry heater (
Table 9). Such a change in heating system efficiency (from 40% to 90%) would reduce the need to extract biomass from poplar buffers by 56% across the whole watershed, creating the opportunity to manage poplar buffers more extensively (see
Section 3.2), with the goal of enhancing services related to canopy closure (stream temperature regulation, habitat or corridor for native forest and stream biodiversity, natural disturbance protection,
etc.). In other words, more multifunctional hybrid poplar buffers could be implemented if energetic needs would be lower for individual farmhouses. However, the replacement of low efficiency appliances by very efficient heating systems can be relatively costly (up to 10,000$ for masonry heaters [
109]), which may delay such technological change in the absence of adequate financial incentives.
There is also uncertainty regarding the estimated LHV of hybrid poplar wood in this study (16.79 GJ/t), which was calculated from hybrid poplar HHV (19.38 GJ/t) found in the literature, without any precision regarding genotype [
66]. HHV may likely change for hybrid poplar clones of different parentages, as large variations in HHV have been reported for the different natural poplar species (16.26 GJ/t for
P. deltoides, 15.00 GJ/t for
P. trichocarpa, 13.50 GJ/t for
P. tremuloides) [
66]. Thus, the selection or development of poplar genotypes that have a high heating value per biomass unit should receive the same attention as selecting the most productive clones. An increase in LHV, alike a biomass yield increase, results in a proportional increase in the number of houses heated with the biomass supply produced in each watershed (
Table 6 and
Table 9). Consequently, for the provision of bioenergy services many initiatives should be undertaken simultaneously, including the use of the most productive clones having high calorific values, an upgrade in heating system efficiency (replacement of old appliances) and a reduction in heating energy needs per unit of area in farmhouses and greenhouses.
In the study area, increase in mean annual temperature and in growing season length resulting from global warming [
110] could also improve hybrid poplar yield and reduce the heating energy requirements in the greenhouse industry and the residential sector; a scenario that would create a positive synergy regarding the number of houses or the greenhouse area that could be heated with poplar biomass produced at the watershed scale. On the other hand, global warming may enhance the dispersal of new pests in the study area, while increasing the severity and/or frequency of natural disturbances [
111,
112]. This situation could increase mortality and negatively affect hybrid poplar productivity and its related services, as hybrid poplars are not very resilient tree species (low mechanical properties and high pest vulnerability) [
113,
114].
Finally, it may be argued that it would be technically difficult to establish hybrid poplar buffers, within a short timeframe, across an entire agricultural watershed in southern Québec. On the one hand, planting hybrid poplars along the 439 km of non-forested farm streams in the Pike River watershed would require 877,690 hybrid poplar bare root plants (395 ha of buffer × 2222 trees/ha), which is well below the yearly production capacity of the provincial nursery that provides hybrid poplar planting stocks in Québec [
26]. On the other hand however, establishing buffers along 439 km of stream in the same year would be hard to achieve because such a large watershed-scale project would require the prompt participation of a large number of landowners. More realistically, 49 km of stream could be afforested each year for the 9 years to come. This would require planting approximately 97,500 trees/year, based on the riparian agroforestry system proposed in this study (see
Section 2.2.1). A gradual implementation of poplar buffers over a nine year period would also create the opportunity to harvest only 1/9 of the total buffer area each year, which would create a mosaic of uneven aged poplar buffers at the watershed scale, while providing a more constant supply of biomass each year for heating farmhouses or greenhouses. Thus, in the Pike River watershed, the afforestation of 49 km of stream per year over nine years would start to generate the annual biomass feedstock required to heat 577–794 farmhouses or 6.5 ha of greenhouses (
Table 7) only at the end of year 9, following the clear-cutting of hybrid poplars along 49 km of stream.
Table 9.
Effect of the variation in heating system efficiency or lower heating value (LHV) of hybrid polar biomass on the usable energy content of biomass, on the biomass requirement per farmhouse and on the number of farmhouses that could be heated for each watershed after 9 years following the replacement of 100% of non-managed herbaceous buffers by hybrid poplar buffers along all streams (perennial + intermittent).
Table 9.
Effect of the variation in heating system efficiency or lower heating value (LHV) of hybrid polar biomass on the usable energy content of biomass, on the biomass requirement per farmhouse and on the number of farmhouses that could be heated for each watershed after 9 years following the replacement of 100% of non-managed herbaceous buffers by hybrid poplar buffers along all streams (perennial + intermittent).
LHV | Heating System Efficiency (%) | Usable Energy (GJ/t) | Biomass (t/house) | Number of Houses Heated per Watershed 1 |
---|
Magog River | Eaton River | Pike River |
---|
New | Old | New | Old | New | Old | New | Old |
---|
16.79 | 40 | 6.7 | 107.2 | 147.4 | 36 | 26 | 135 | 99 | 524 | 381 |
16.79 | 50 | 8.4 | 85.8 | 117.9 | 45 | 33 | 169 | 123 | 654 | 476 |
16.79 | 60 | 10.1 | 71.5 | 98.3 | 54 | 40 | 203 | 148 | 785 | 571 |
16.79 | 70 | 11.8 | 61.3 | 84.2 | 63 | 46 | 237 | 172 | 916 | 666 |
16.79 | 80 | 13.4 | 53.6 | 73.7 | 73 | 53 | 271 | 197 | 1047 | 762 |
16.79 | 90 | 15.1 | 47.7 | 65.5 | 82 | 59 | 305 | 222 | 1178 | 857 |
10.00 | 60.6 | 6.1 | 118.8 | 163.3 | 33 | 24 | 122 | 89 | 473 | 344 |
12.00 | 60.6 | 7.3 | 99.0 | 136.1 | 39 | 29 | 147 | 107 | 567 | 413 |
14.00 | 60.6 | 8.5 | 84.8 | 116.6 | 46 | 33 | 171 | 125 | 662 | 481 |
16.00 | 60.6 | 9.7 | 74.2 | 102.1 | 52 | 38 | 196 | 142 | 756 | 550 |
18.00 | 60.6 | 10.9 | 66.0 | 90.7 | 59 | 43 | 220 | 160 | 851 | 619 |
3.2. Hybrid Poplar Buffers for Maximum Multiple Ecosystem Services and Fewest Disservices
Other ecosystem services than those quantified in the previous section may be provided if hybrid polar buffers are implemented at a watershed scale and those potential services should be considered altogether in the design of poplar buffers. One of the major challenges is how to design and manage such riparian buffers for the provision of multiple ecosystem services, while avoiding or mitigating potential disservices [
21]. This section provides a holistic view of the different ecosystem services (including goods) that may be provided by poplar riparian buffers, while identifying potential trade-offs and management recommendations to optimise services and reduce disservices.
Table 10, presented at the end of this section, integrates all of this information.
Concerning regulation services, the previous section has presented results of the potential of poplar buffers for stocking large amounts of nutrients (N and P) in biomass, a process closely linked to nutrient uptake by trees during the growing season. Reduction of more than 50% in the availability of soil nitrate (NO
3) and P during summer was observed in hybrid poplar buffers when compared to adjacent herbaceous buffers [
35]. However, poplar buffers can also reduce non-point source nutrient pollution outside of the growing season, especially when the poplar rhizosphere can interact with groundwater. For example, groundwater NO
3 retention, during winter months, reaches almost 100% in the first 5 m of a poplar buffer (probably because of denitrification), an efficiency that was higher than that of an adjacent herbaceous buffer [
44]. Such reduction in nutrient loads to streams would also increase stream C sequestration, as instream decomposition of terrestrial litter is co-limited by water N and P concentrations [
115]. Therefore, creating a new terrestrial sink for atmospheric CO
2 and excess soil nutrients with poplar riparian agroforestry would also reduce C losses associated to instream organic matter mineralisation, which would have a cumulative positive effect on the global climate regulation service. Microbial activity in the poplar rhizosphere and pesticide uptake/transformation by poplars may also contribute to agrochemical pollution mitigation [
116,
117]. Additionally, rapid height growth of poplar buffers creates a physical barrier that can reduce aerial pesticide drift into streams and wetlands.
The development of key structural attributes also increases the strength of riparian vegetation/stream interactions. Such interactions improve regulation and habitat provision services in stream ecosystems. Even in narrow poplar buffers, canopy closure can be almost complete as early as six years along headwater streams (
Figure 3a). Canopy closure improves stream shading, reduces periphyton blooms [
118], maintains cooler water temperatures [
48], and allows inputs of terrestrial invertebrate prey into streams [
119]. Buffers with rapid canopy development would be particularly needed along small streams in open fields, as predicted increases in water temperatures resulting from global warming may exceed the thermal tolerances of some aquatic species [
120].
Planting broadleaved trees along farm streams also enhances leaf litter inputs (
Figure 3b), which can restore trophic relationships in aquatic ecosystems [
121], while contributing to higher instream nutrient retention and C sequestration [
11,
122]. It should be highlighted that stream invertebrates select litter largely on the basis of its food quality, whether it is from exotic hybrid poplars or native species [
123]. Hybrid poplar litter is known to be rapidly consumed by benthic stream invertebrates because it is N-rich and soft [
123]. Thus, hybrid poplar leaf litter would locally enhance the detrital energy base of streams, even in streams with lower litter retention capacity [
122,
123]. Poplar roots growing directly into stream water can further provide energy to the stream food web, while contributing to instream C sequestration and nutrient uptake (
Figure 3c). Additionally, increase of stream water and riparian zone soil temperatures resulting from riparian forest clearing have been linked to increasing fluxes of several greenhouses gas (N
2O, CH
4 and CO
2), [
124]. Consequently, cooler temperatures provided locally following riparian tree canopy restoration would have high potential for greenhouse gas mitigation in riparian zones and in stream ecosystems.
The rapid development of large tree stems in streamside habitats is another important structural element of poplar buffers. Tree stems reduce flow velocity during flooding events and allow woody debris and sediment accumulation in the riparian zone (
Figure 3d), thereby protecting infrastructures located downstream. Forest vegetation also provides much greater channel and bank stability, than herbaceous vegetation [
11,
125]. Although bank erosion is a desirable feature of natural stream ecosystems [
126], too much bank erosion along channelized farm streams can reduce water quality and impair stream habitats [
11], as bank erosion is a major contributor of suspended sediments and P [
127]. Therefore, when replacing herbaceous vegetation, poplar buffers are expected to reinforce streambanks (
Figure 3e), as they rapidly form deep and extensive root systems along degraded farm streams [
43]. Rooting depths of more than 5 m have been reported in natural riparian poplar stands [
128], while rooting depths exceeding 3 m have been reported in four-year-old hybrid poplar plantations [
129]. In a context where the frequency and magnitude of storm flow events are exacerbated by agricultural land use and by global warming [
130,
131], streambank reinforcement with deep-rooted poplars could be important to prevent high rates of erosion. Such a streambank stabilisation strategy with poplar plantings was already used two millennia ago by native North Americans [
27].
Another important structural attribute of poplar buffers, is that they can become a source of large deadwood for streams on a decanal timeframe (
Figure 3f). As reviewed by Pollock and Beechie [
132], the major role of riparian forests in enhancing stream biodiversity is to produce sufficient deadwood of different sizes to form complex wood jams, which further contribute to sediment trapping, water velocity reduction, pool formation, and complex stream or riparian habitat creation. While it may take several decades to form such complex wood jams following the regrowth of natural forests [
4], planting hybrid poplar genotypes that have a forking stem habit and a low wood density could accelerate the production of large woody debris in riparian areas [
42]. Individual trees that fall into the stream also contribute to pool formation, while providing cover for aquatic organisms [
132], and additional substrate for instream microbial denitrification [
133].
Figure 3.
(a) Canopy closure shown by a hemispherical photo taken above a headwater farm stream protected by a 6 year-old poplar buffer (Brompton, QC, Canada); (b) leaf litter input to stream from a 9 year-old poplar buffer (St-Isidore-de-Clifton, QC, Canada); (c) instream poplar root development in a 12 year-old poplar buffer (Magog, QC, Canada); (d) woody flotsam interception and flood sediment deposition in a 9 year-old poplar buffer (Bedford, QC, Canada); (e) important colonisation of a streambank by tree roots in a 9 year-old poplar buffer (Brompton, QC, Canada); (f) large woody debris naturally fallen in the stream zone in a 12 year-old poplar buffer (clone MxB-915311, Magog, QC, Canada).
Figure 3.
(a) Canopy closure shown by a hemispherical photo taken above a headwater farm stream protected by a 6 year-old poplar buffer (Brompton, QC, Canada); (b) leaf litter input to stream from a 9 year-old poplar buffer (St-Isidore-de-Clifton, QC, Canada); (c) instream poplar root development in a 12 year-old poplar buffer (Magog, QC, Canada); (d) woody flotsam interception and flood sediment deposition in a 9 year-old poplar buffer (Bedford, QC, Canada); (e) important colonisation of a streambank by tree roots in a 9 year-old poplar buffer (Brompton, QC, Canada); (f) large woody debris naturally fallen in the stream zone in a 12 year-old poplar buffer (clone MxB-915311, Magog, QC, Canada).
Poplar buffers also provide refuge for terrestrial and wetland biodiversity on farmland. Bird nests have been observed five years following hybrid poplar establishment along farm streams (
Figure 4a). Additionally, the particular rooting habit of some poplar genotypes may serve as a structural element for burrow placement (
Figure 4b). The soft wood of hybrid poplars is also very attractive to woodpeckers [
31], which produce cavities that can provide further nesting and roosting habitat for other cavity-using species (mammals, birds, reptiles, amphibians and insects) [
134]. One hybrid poplar genotype (clone DNxM-915508) appears to be particularly used for feeding by the yellow-bellied sapsucker (
Sphyrapicus varius) (
Figure 4c) [
31]. Even pileated woodpeckers (
Dryocopus pileatus), generally associated with interior habitat of mature forests [
135], have been observed feeding on dead poplars of a five-year-old buffer that was isolated from the nearest forest patches (J. Fortier and B. Truax, field observations). Small mammals typical of forest habitats (
Napaeozapus insignis,
Peromyscus maniculatus and
Sorex cinereus) have also been captured in a 9-year old poplar buffer that was connected to an adjacent forest habitat, which suggests that some forest species will use poplar buffers as corridors [
31]. On the other hand, a crop damaging species typical of open habitats, the meadow vole (
Microtus pennsylvanicus) [
136], was captured in herbaceous buffers, but not in the poplar buffers [
31]. Predators of crop damaging species, such as the short-tailed weasel (
Mustela erminea) have equally found refuge in hybrid poplar buffers (
Figure 4d). Although they usually have lower conservation value than natural forests, numerous studies confirm the role of planted poplars as a refuge for wildlife on farmland [
137,
138,
139,
140,
141]. Moreover, pest control in cropping systems may be improved by the integration of linear poplar structures in agro-ecosystems because such structures can become reservoirs of beneficial insects (predators and parasitoids) [
140]. By providing shade, wind protection and reduced herbaceous vegetation cover, poplar buffers can also provide a favourable environment for the restoration of more shade-tolerant native tree or herb species, which can be under-planted or regenerate naturally (
Figure 4e,f) [
29,
30,
142,
143,
144]. Additionally, rapid canopy closure in poplar buffers can reduce the abundance of shade-intolerant introduced (exotic) herbaceous species, which includes many agricultural weeds [
30].
Figure 4.
(a) A bird nest in a 5-year old hybrid poplar buffer (Brompton, QC, Canada); (b) a burrow in a 9-year old poplar buffer (clone MxB-915311, St-Isidore-de-Clifton, QC, Canada); (c) small cavities created by the yellow-bellied sapsucker (Sphyrapicus varius) to attract insects on which it feeds (clone DNxM-915508, Roxton Falls, QC, Canada); (d) use of a 9-year old hybrid poplar buffer for hunting and den making by a short-tailed shrew (Mustela erminea) (Magog, QC, Canada); (e) 5-year old red oak (Quercus rubra) planted on top of the streambank in a gap following a partial poplar harvest; (f) naturally established native wetland herbs (Impatiens capensis (in foreground) and several species of Carex) in a 6-year old hybrid poplar buffer (Brompton, QC, Canada).
Figure 4.
(a) A bird nest in a 5-year old hybrid poplar buffer (Brompton, QC, Canada); (b) a burrow in a 9-year old poplar buffer (clone MxB-915311, St-Isidore-de-Clifton, QC, Canada); (c) small cavities created by the yellow-bellied sapsucker (Sphyrapicus varius) to attract insects on which it feeds (clone DNxM-915508, Roxton Falls, QC, Canada); (d) use of a 9-year old hybrid poplar buffer for hunting and den making by a short-tailed shrew (Mustela erminea) (Magog, QC, Canada); (e) 5-year old red oak (Quercus rubra) planted on top of the streambank in a gap following a partial poplar harvest; (f) naturally established native wetland herbs (Impatiens capensis (in foreground) and several species of Carex) in a 6-year old hybrid poplar buffer (Brompton, QC, Canada).
Concerning production services, poplar buffers can be used to diversify farmland economy by providing biomass for bioenergy and biofuels [
32,
33,
34,
145], but also raw material for pulp and paper, lumber, veneer, plywood, composite panels, structural composites, containers, pallets, furniture components, match splints and chopsticks [
76] (
Figure 5a,b). Bioproducts from poplars (propolis, flavonoids, bud extracts) have also various applications in medicine, health foods, cosmetics and plant disease control [
146,
147]. Poplar foliage and rameal wood are currently used as an inexpensive fodder during drought or as supplements to increase livestock reproductive capacity [
148,
149]. Litter fall from poplar buffers reaching adjacent cropping systems can contribute to improving soil fertility and food crop productivity [
150]. Planted poplars are also naturally colonised by a wide array of fungi, including the oyster mushroom (
Pleurotus ostreatus), a well-known edible mushroom [
151] (
Figure 5c), which can also be cultivated on poplar logs.
Furthermore, a watershed scale implementation of poplar riparian buffers could provide some cultural services. The use of poplar buffers by different bird species could improve farmland value for bird watching, while the improvement of instream and riparian habitats following buffer implementation could be beneficial for game hunting and fishing. A major issue that remains is how well these novel riparian ecotones will be perceived among rural communities, as tree buffers may close up open landscapes and compete with traditional agricultural land use [
152,
153,
154]. Still, poplar buffers composed of various genotypes that have different shades of yellow in their autumn foliage and different tree architectures could improve the aesthetic value of agricultural landscapes (
Figure 5d–f), especially in areas where extensive crop monocultures currently dominate.
Figure 5.
(a) Fuelwood (biomass) production following partial harvest in a 6-year old poplar buffer (Brompton, QC, Canada); (b) pruned hybrid poplar buffer for the production of solid wood products; (c) Pleurotus ostreatus, a native edible mushroom, naturally growing on a decaying hybrid poplar (Brompton, QC, Canada); (d–f) hybrid poplar buffers in various farmland settings.
Figure 5.
(a) Fuelwood (biomass) production following partial harvest in a 6-year old poplar buffer (Brompton, QC, Canada); (b) pruned hybrid poplar buffer for the production of solid wood products; (c) Pleurotus ostreatus, a native edible mushroom, naturally growing on a decaying hybrid poplar (Brompton, QC, Canada); (d–f) hybrid poplar buffers in various farmland settings.
What could place additional limitations on ecosystem service provision by poplar buffers? First, it is widely assumed that buffer width is a major factor affecting regulation and habitat provision services [
6,
9,
11,
20,
48,
87,
99]. The legal context related to riparian zone management can also be an obstacle for the production services that require tree harvesting, as some jurisdictions restrict such activities. In addition, many ecological, hydrological and biogeochemical functions/services provided by tree buffers depend on their level of spatial connectivity with adjacent stream ecosystems, with remnant natural riparian forests, with upland habitats, and with groundwater [
155]. Thus, the restoration of some services will require particular spatial configurations or specific locations in watersheds (ex: habitat provision, corridor for dispersal of plants and animals, stream shading, flood control, groundwater purification), while some other services are independent of spatial configuration within landscapes (e.g., C storage, wood production) [
21,
156]. Therefore, for some services, the establishment of buffers across multiple boundaries will require a high level of cooperation between private landowners, which may complicate implementation [
156].
In many agricultural areas, establishing tree buffers alone may not be sufficient to promote stream biodiversity. As argued by Parkyn
et al. [
48], proximity to a source of colonists and the presence of colonisation pathways may be of overriding importance to allow rehabilitation of stream organisms such as invertebrates. Additionally, many studies suggest that riparian zone quality, in terms of forest cover, is not a significant factor affecting stream biodiversity, with actual or past land use type across the whole watershed being the dominant factor [
131,
157,
158,
159,
160,
161]. Still, a 20 m wide hybrid poplar buffer (20 years old) established along 3.6 km of a 5 m wide farm stream, was found to positively affect stream habitat quality (reduction in stream water N and P, increased water clarity, temperature reduction), which lead to invertebrate community improvement [
48].
However, in watersheds where agricultural development has increased hydrological connectivity between the land and streams, some level of hydrological restoration is a prerequisite to stream biodiversity enhancement [
162]. In such a context, efforts should first be invested at retaining storm waters upland, in order to create more natural flow regimes [
162]. Then, best management practices aiming at reducing contaminant load to streams should be used [
162]. Once these issues are resolved, the improvement of stream structure can be undertaken, if necessary [
162].
Given that poplars are among the beaver’s (
Castor canadensis) favorite foods, the presence of beavers in lowland streams is another factor that could seriously affect the structure and function of poplar buffers [
163], especially in flood prone areas [
164]. Equally, the presence of a subsurface drainage system may be a limitation for the planting of phreatophytic poplars, as their root systems may obstruct subsurface drains [
43]. However, this potential disservice has not been adequately studied and its relative importance is unknown.
The level of human intervention (tree harvest, tree pruning, enrichment planting) following buffer establishment will also greatly affect a series of ecosystem services (
Table 10). Consequently, managing poplar buffers for intensive biomass production and nutrient exportation, for extensive or semi-intensive wood production, or for riparian forest reconstruction will not lead to the same output in terms of ecosystem service provision (
Figure 6). Thus, a complex mosaic of poplar buffers with different management regimes and designs could be created at the watershed level, depending on farm-scale objectives and biophysical characteristics, but also depending on stream rehabilitation targets. Finally, while multiple genotype buffer systems should always be used to improve resilience [
55], developing, selecting and spatially positioning the right genotypes for the provision of specific ecosystem services would greatly improve the performance of poplar buffers planted for multi-functionality (
Table 10) [
27].
Figure 6.
Examples of the different management options available following hybrid poplar buffer establishment in agricultural riparian zones. Potential levels of ecosystem service or function supply within the different buffer management types are indicated (* low; ** moderate; *** high, ? uncertain).
Figure 6.
Examples of the different management options available following hybrid poplar buffer establishment in agricultural riparian zones. Potential levels of ecosystem service or function supply within the different buffer management types are indicated (* low; ** moderate; *** high, ? uncertain).
Table 10.
Overview of potential ecosystem service and disservices following the replacement of non-managed herbaceous buffers by hybrid poplar buffers. Management considerations for services optimisation and disservices mitigation are also provided.
Table 10.
Overview of potential ecosystem service and disservices following the replacement of non-managed herbaceous buffers by hybrid poplar buffers. Management considerations for services optimisation and disservices mitigation are also provided.
Ecosystem Services | Functions, Processes, Structures and Traits Related to Ecosystem Services | Potential Trade-Offs or Disservices | Optimisation and Mitigation Strategies |
---|
Regulation | | | |
Non point-source pollution control/water quality protection | Fast-growth, high water uptake, high N and P concentration in tissues, and perennial nature of poplars allow high rate of nutrient uptake/accumulation and long-term storage in woody biomass [ 35, 40, 163].
| | |
| Introduction of hybrid poplar leaf litter in degraded farm streams can increase instream N and P retention due to bacterial immobilisation [ 122].
| | |
| Extensive lateral rooting [ 167, 168] allows nutrient capture beneath adjacent pastures and crops.
| Poplar lateral roots can compete with adjacent agricultural crops for water and nutrients [ 169].
| At the buffer/field interface, plow soil or prune roots with a ripper knife to reduce tree competition with crops near the soil surface [ 170].
|
| Rooting depths greater than 3 m allow nutrient capture at different soil depths and in groundwater [ 129, 171] and could increase depth of active denitrification zone [ 172]. Poplar buffers can increase denitrification in the dormant season [ 44].
| | Use long whips planted at >1 m deep in soil to help increase C input at depth and nutrient uptake in groundwater [ 173].
|
| Poplar rhizosphere supports microbial community important for bioremediation processes [ 116]. Poplars can uptake, store and transform some pesticides [ 117].
| | Use clones having high rates of root exudation and fine root production to increase soil microbial activity and bioremediation [ 174, 175].
|
| Instream poplar root growth allows nutrient uptake directly from water in farm streams [ 43].
| Poplar roots may enter subsurface tile drains and reduce field drainage [ 43].
| |
| Riparian buffer zones with tall trees efficiently reduce pesticide drift in water bodies [ 176].
| | |
Local and global climate regulation | Poplar buffers create a new and fast-growing biomass C sink on farmland [ 35, 163, 177]
| | |
| Poplar buffers improve stream and riparian zone shading [ 30] and can lower stream temperature [ 48, 179]. Streamside tree canopy development may reduce GHG emissions by reducing stream and riparian soil temperature [ 124].
| Linear structures of poplar can shade crops and reduce yields, especially on north side [ 180]. Poplars can shade out understory herbaceous vegetation [ 30] and reduce its runoff interception capacity. Reduction in periphyton biomass because of tree shading may increase dissolved nutrients in streams [ 118].
| Near the stream, use clones with a dense canopy and larger crowns, and maintain closed canopy, to maximise light interception and temperature reduction of soil, air and water. At the field edge, use clones with a small crowns and prune trees to reduce light competition with crops and to improve understory herbaceous growth.
|
| | | |
| The mitigation of agricultural N and P pollution by riparian buffers may improve stream C storage by limiting terrestrial input decomposition [ 115].
| | |
Disturbance and water regulation | Tree stems and fallen woody debris reduce flow velocity and flood damages [ 181]. Windbreak effect of trees in open areas reduces wind velocity, storm impacts, while enhancing snow accumulation in semiarid regions [ 182]. Tree vegetation allows greater infiltration of surface runoff [ 4, 183]. Decaying tree roots create macropores in streambank soil, which improves water storage capacity during storm events [ 184].
| | |
| Planted poplars have a similar water yield to hardwood forests, and can reduce peak flow and spring floods on farmland [ 187]
| In dryer climate or in wetland habitats, planted poplars can adversely affect local water balance because of their high water use [ 188, 189].
| Select clones with high water use efficiency in sensitive habitats (wetland margins, dry climate) [ 190].
|
Soil protection and formation | Streamside poplar plantings improve streambank stability [ 125, 191].
| Riparian afforestation may increase short-term erosion rate along incised channels and contribute to channel widening [ 192, 193].
| |
| Poplar afforestation can increase soil C stocks over the long term [ 58, 62]
| Poplar afforestation can reduce soil C over the short term [ 43, 58].
| |
| Windbreak effect of tree buffers can reduce arable soil erosion [ 182].
| | Maintain a continuous linear tree structure to optimise the windbreak effect [ 182].
|
Biological control | Poplar canopy provides a shade barrier reducing riparian zone invasion by shade-intolerant exotic plants [ 30]. Poplar canopy can reduce weed biomass in riparian zones [ 30]. Poplar buffers can reduce the abundance of meadow vole ( Microtus pennsylvanicus), a crop damaging mammal [ 31]. Linear poplar structures are reservoirs of beneficial insects (predators and parasitoids) in agroecosystems [ 140].
| | |
Habitat Provision | | | |
Refuge and nursery for terrestrial biodiversity | | Poplar afforestation in natural grassland ecosystems can reduce native plant diversity [ 197]. Predators (fox, coyote, wolf) of livestock and crop damaging species (deer, elk) may use tree corridors to travel on farmland [ 198]. Heavy poplar browsing by cervids and beaver can results in poor tree survival/establishment [ 104, 163, 164, 199], and thus poor ecosystem service provision. Riparian corridor composed of exotic poplars can lead to genetic pollution of native poplar stands [ 200]. Poplars are hosts of many diseases and insects [ 28].
| Optimize spatial and structural heterogeneity and use longer rotations [ 141, 201, 202]. Maintain tree cover at the landscape scale. Use multiple clones with different tree architectures and longevity. Use clones that break easily (wide crowns, forked stems, low wood density), cut some poplars down and retain dead trees to provide coarse woody debris and snags. Notch or girdle living poplars for enhancing woodpecker food sources and habitats [ 203]. Under-plant native hardwoods, conifers and riparian/wetland herbs. Use genotypes with large lateral branches for bird nest placement [ 204]. Protect trees with metallic mesh to avoid beaver damage or trap beavers. Use Tacamahaca section related clones to reduce browsing by cervids [ 104]. Use large planting stock in wilder areas [ 205]. Avoid planting exotic poplars near small isolated natural poplar stands [ 206], or use native genotypes.
|
Refuge for aquatic biodiversity | Temperature regulation, improved water quality and clarity by poplar buffers enhance stream biodiversity [ 48]. Hybrid poplar litter input can increase stream invertebrate abundance and diversity in farm streams [ 123]. Hybrid poplar buffers can become source of large deadwood within a decade [ 42].
| | |
Production | | | |
Raw materials and energy | | Clear-cutting of poplars can cause soil erosion and instream sediment pollution [ 210]. Use of heavy machinery for harvest can cause soil compaction [ 211], which could reduce water infiltration in soil and pollutant trapping efficiency. Tree harvest can impinge on ecosystem services related to canopy closure (biological control, habitat provision, aesthetic value, etc.).
| Use rotational or partial harvest to maintain a tree structure at the landscape level and to reduce erosion [ 210, 212]. If heavy machinery is used for harvesting, wait for frozen ground to reduce soil compaction [ 213], and avoid traffic on streambanks. Select clones with higher wood density and low branch biomass, and prune trees and use a lower stand density to produce high quality logs. For bioenergy production, select productive clones with a high energy content per unit of biomass.
|
Food | Poplar foliage and rameal wood can be used as a fodder for livestock, but also as a supplement to increase reproductive capacity [ 148, 149]. Poplar litter has a positive effect on adjacent farm soil fertility [ 150]. The windbreak effect of trees can increase crop yield and offer protection to livestock [ 182]. Decaying trees in poplar plantations can be naturally colonized by Pleurotus ostreatus, an edible mushroom [ 151]; poplar logs can also be inoculated with this fungus.
| Poplar leaves can accumulate heavy metals from contaminated soils at concentrations that are harmful for livestock [ 27]. Field margin trees can compete with nearby crops for resources. Buffer establishment can be made at the expense of cultivated areas. Heavy poplar browsing by livestock will reduce growth and may cause mortality.
| Select clones with higher protein or N content in branches and foliage to feed livestock, and test soil and poplar tissues for heavy metal contamination. Select clones with smaller crowns to reduce competition for light with crops, prune roots or plough soil at field edge to reduce root competition [ 170]. In pastures, fence riparian buffer to avoid livestock damage (ideally with an electric fence).
|
Bioproducts | Propolis, which has applications in medicine, health foods and cosmetics, can be produced from different poplar species [ 146]. Antimicrobial flavonoids from poplar twigs have applications in plant disease control [ 147].
| | |
Cultural | | | |
Recreation | Contribution of tree buffer to stream, riparian and terrestrial biodiversity, but also to water quality, could improve recreational value in rural areas (sport fishing, hunting, bird watching, swimming, etc.).
| | Increase structural heterogeneity and complexity, and plant biodiversity. Develop access to riparian zones in agricultural areas. Maintain closed canopy to lower stream temperature and to provide inputs of terrestrial invertebrates. Maximise nutrient and sediment pollution removal by buffers.
|
Aesthetic | Planted floodplain poplars may be seen as beautiful and useful elements of rural landscapes [ 214].
| | Open scenic views by thinning and pruning, or avoid tree planting obstructing scenic views. Use a variety of clones with different tree architectures and shades of yellow in their autumn foliage to increase visual quality of farm landscapes.
|