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Article

Improvement of the Plantation Success in a Crib Wall in a Mediterranean Hydro-Meteorological Risks Scenario—Practical Results

1
Naturalea Conservació SL, 08211 Castellar del Vallès, Spain
2
CREAF, Centre de Recerca Ecològica i Aplicacions Forestals, 08193 Cerdanyola del Vallès, Spain
*
Author to whom correspondence should be addressed.
Sustainability 2021, 13(21), 11785; https://doi.org/10.3390/su132111785
Submission received: 2 July 2021 / Revised: 13 October 2021 / Accepted: 18 October 2021 / Published: 25 October 2021

Abstract

:
Due to the clime change scenario, severe hydro-meteorological phenomena are having a high impact on the ecosystems of the earth. Some strategies based on the use of natural communities associated with geomorphological changes that restore the natural landscape are gaining success due the resistance and resilience against damages. All of these strategies are known as nature-based solutions (NBS). Soil and water bioengineering techniques are one of the most appreciated tools to reach effectiveness for slope stabilization. They are based on the capacity of some plants to consolidate the soil with his rooting system in special conditions (high slope, flooding impact). Slope stabilization solutions with soil and water bioengineering techniques need to be adapted to this new scenario. Crib wall is one of the most complete soil and water bioengineering technique for structural slope stabilization. It is based on a wooden box full of live plants that in the future will grow and gain stability at the same time that wood decays. The crib wall box is full of soil, and the front area is traditionally stabilized with some branches of fascines to let plants grow, maintaining the structure. Fascines are made of branches of riparian species with the capacity for vegetative propagation. Their diameter can change due to the humidity variation, so the stiffness of the system is at risk against severe hydro-meteorological phenomena. This study aims to assess that the introduction of HDCL in crib walls improves planting success and makes them more resistant to adverse weather events in Mediterranean areas. Four experiments were performed in controlled and natural conditions with this proposal. The results show that the use of natural fibers instead of branch fascine helps to maintain the humidity conditions and increase the resistance capacity. High-density coir logs (HDCL) are not affected by volume changes for humidity conditions. HDCL maintains the plant’s humidity conditions longer and makes plants grow faster, bigger and increase their survival. This method of Crib wall construction increases the associated biodiversity. The most important results are that the use of HDCL in crib walls has an effect on the growth of planted shrub, the development of roots, the colonization of native vegetation and ultimately, the resistance of the structure to the floods. The results also show that crib walls are a good technique for the stabilization of slopes with considerable gradients and high hydraulic impacts. HDCL can reduce the water stress of plantations, and they can be a good system to retain runoff and provide it to the plants. Finally, the HDCL allows the revegetation of a crib wall 30% faster than with branch fascine.

1. Introduction

A crib wall (Figure 1) is one of the most widely used soil bioengineering techniques, consisting of wooden structure logs forming a three-dimensional cell backfilled with soil. On the front of the crib wall are placed live stakes or container plants, with the aim that the future development of the plants replaces the structure of logs [1]. The crib wall structure is linked to the history of civilization. There are foundations of crib walls on Roman bridges 2000 years BP. The walls of the Celtic villages were likely a type of crib wall. However, it is not easy to find shreds of evidence of these works. Pareto [1886] describes the origin of the crib wall technique, which reports examples of log revetments proposed by Sir Culmann for the Eschibach torrent control near Berna with wood structure and stones [2]. However, the current log-wood crib wall system in slopes was originally developed in a place called “Kranj” in north Slovenia. This wall system is famous under the name “Krainerwand” in German-speaking countries [1]. Today, the word Krainer is a popular name for a vegetated crib wall of double wall.
In the eastern Alps, crib walls were a usual slope retention system and were made of wooden boxes filled with rocks [3], but this system has a relatively short shelf life due to the durability of the deadwood. In 1934, Hassenteufel introduced willow plants instead of rocks; the plants occupied the space of the rotting lumber, and the structure became permanent. The only change is the slope that they valued in a proportion of 1:10 [4]. In order to keep the soil in the structure and let plants grow, a plant fascine is used to close the holes between trunks in the front area. Fascines come from the Latin “fascinare”, which means binding bundling. This fascine develops an essential role in moisture retention. Schemerl, in 1818 [4], already reported the use of fascines for streambank protection [3]. The evolution of this system is used worldwide today.
The actual crib walls are the evolution of the Hassenteufel works. The decomposition of the wood accelerates in the surface of the cut and the holes of subjection (for nails or corrugated bars). Therefore, today, we construct crib walls in the simplest way: without laces of wood and nails to achieve resistance
The structure always needs a foundation, determined according to its location. Depending on the level of transient erosion, the depth at which the structure must be anchored is established. If a crib wall is used as a structural wall to stabilize margins and the structure must support heavy loads, it is recommended reinforced crib wall with double-wall or Krainer. The front of the live crib wall has to be inclined to reach a maximum slope gradient of 60°. When the crib wall is lifted, the logs that follow the line of elevation in the length of the structure are placed down until they are aligned with the back of the lower log.
Fascines are made by branches of trees and shrubs generally collected close to the job side area. It is clear that most of the usual trees used have a big variation in volume due to the variations in climatic conditions. Wood is a hygroscopic material in which the space between its microfiber varies according to the water content (Table 1). As a result, the volume of the wood increases with moisture and decreases with drying as long as the fibers are not saturated with moisture. Volumetric contraction is the property used to measure the increase (swelling) or decrease (decrease) in the volume of wood when taking or giving water from or to the environment. In addition, there is also the coefficient of volumetric contraction, used to measure the volumetric variation in a wood that, below the saturation point of the fibers, varies its moisture by 1% [5]. The data show that in the case of a fascine made from all wood, the volumetric concentration changes are between 13% and 17%.
If fascines located in crib wall reduce their diameter, three situations can happen: the soil can escape, air can enter and dry the roots, or water can enter during storms and empty the crib wall wooden box. For this reason, in the last years, in several bioengineering works but especially in crib walls in the Mediterranean area, we used coconut HDCL instead of fascines. The coir, coconut fiber (Cocos nucifera L.), are the longest stable natural fibers because of its peculiar proprieties such as the high percentage of lignin, the 41–45 wt% [6]. In 1976, Lothar Bestmann (in Hamburg, Germany) began a line of slope bioengineering works based on the use of high-density coir logs (HDCL). As a result, plants developed a root system within the fibers before their degradation and took advantage of the fibers’ moisture. The HDCL is a hydrodynamic structure formed by a compressed and structured coconut fiber cylinder with a polypropylene/coir net that can withstand long periods of significant water passages at high speeds together with the fixing of stakes and rope.
Depending on the high density, a coir log fiber can be washed apart. After years of research based on practical works, the standard stock item Naturalea develops quality criteria (unpublished data). The coir rolls (HDCL) are manufactured from coir fiber with a mean fiber length of 150 mm ± 50 mm, compressed to a density of 110–120 kg/m² and contained by a net of 2 mm PP yarn or 5 mm coir yarn with a mesh size of 50 mm. The dry weight is 9 ± 0.5 kg/lin.m. Regarding the wet weight, we established the criteria 1 h after removal from the water to be approx. 20.6 kg/lin.m.; 4 h after removal from the water, it was established to be approx. 16.7 kg/lin.m. Finally, when subjected to a load of 80 kg, the Coir roll compresses less than 15% (this load approximates to an 80 kg man standing on the roll) [6,7].
This paper aims to analyze how to improve plantation success, and one of the tools is the use of coconut HDCL in crib walls.
In order to obtain a more systematic analysis, we evaluated four different parameters or characteristics:
(A)
Improve the resistance to hydro-meteorological hazards. In order to establish if HDCL structures resist flooding events, and especially areas with high flooding, we obtain data on shear strength, velocity and peak flow from the avenues that affected the works carried out with this product/technique;
(B)
Effects of HDCL on the growth and survival of plants. Especially establishing if HDCL in arid conditions will compete for water with roots and dry out the plant;
(C)
The colonization of HDCL by plant roots in comparison to standard soil mixture in natural areas or with nursery plants. To obtain faster root growth, we used helophyte plants;
(D)
The success of crib wall soil bioengineering works with different characteristics and scenarios with the use of HDCL.

2. Material and Methods

2.1. Improving HDCL Resistance to Hydro-Meteorological Hazards

2.1.1. Study Sites and Experimental Design

In order to establish the resistance of vegetated HDCL, an analysis of the conservation conditions of vegetated fiber rolls (HDCL) installed in rivers was performed. We consider that conservation conditions are good when the plants are regularly distributed and maintain the initial structure of hard density in 30 cm diameter. We selected different case studies in which HDCL were installed directly (Table 2). In crib walls, the HDCL has extra protection because it has wooden trunks in all the perimeter. We selected several job sites where vegetated HDCL fiber rolls were installed; interventions that we carried out in the Mediterranean area in twelve different locations throughout Catalonia (northeastern area of Spain). A set of study areas with jobs conducted between 2000 and 2009 was chosen, and we obtained official data from the Catalan Agency of Water to establish the flood events that affected the different places.

2.1.2. Sampling Design and Data Collection

All the study areas were visited, and to obtain data from the area, we made a cross-section of the river and obtained data on the lithology of the river banks. We found that the HDCL vegetated has vegetation in all lengths and that the roll maintains the volume, so there are no holes due to fibers being dragged away. The data on peak flow and water speed that affects the area since HDCL implementation were selected from the automatic register of the nearest gauging station in each study area, provided by the Catalan Water Agency.

2.1.3. Data Calculation and Statistical Analysis

Hydraulics of the study area were analyzed, considering shear stress, flow and peak velocity from the implementation until now. The hydraulic study was carried out with the Manning formula and Master Flow software; bed shear stress (Babaeyan-Koopaei et al., 2002).

2.2. Influence of HDCL on Growth and Survival of Plants

2.2.1. Study Sites and Experimental Design

We carried out a specific design located in the Urban River Lab experimental facility (http://www.urbanriverlab.com) (accessed on 17 October 2021), which is outdoor research (mesocosm) located in Montornès del Vallès (Barcelona, Catalonia). The facilities are located on one of the quaternary terraces of the Besòs River. The composition oef the soil is basic, with a dominated granulomere of silts, clays and gravels.
The experimental setting consisted of 3 parallel lines of 18 m in length, which were planted in a line, with a spacing of 0.5 m from each other (Figure 2). A total of 36 plants were in the forestry cell, which came from a plant nursery. The first planted line did not have coconut HDFL (control); the second one had a line of coconut HDFL 30 cm in diameter, tied in coconut net partially buried next to it (treatmentF1); and the third line had between 2 parallel lines of HDFL that separated 0.5 m (treatment F2). In each planting line were placed 12 individual plants from each species that are widely used in bioengineering in Southern Europe, especially in Mediterranean regions: Viburnum tinus L. (an evergreen shrub widely distributed [8]), Pistacia lentiscus L. (another evergreen shrub or small tree that is 1–8 m tall, which grows in many Mediterranean countries) [9] and Lavandula angustifolia L. (widely distributed aromatic herb [10]).
Throughout the experiment, these adventitious plants were manually extracted and watered on the day of planting and three more times before sampling with the amount of water proportional to the average rainfall in autumn in Montornès del Vallès.

2.2.2. Sampling Design and Data Collection

The sampling period began three months after planting, once the plants had adapted to the new conditions. From the first sampling time, in September, the sampling frequency was set at 20 days. Five samplings were carried out (day 90, 110, 130, 150 and 176).
For each plant and sampling day, we measured the following parameters: aerial diameter—in order to establish the vertical development of the plant, the aerial height was measured; in order to establish the vigor of the plant, a visual estimate of the percentage of the living plant and a mortality count was provided.

2.2.3. Data Calculation and Statistical Analysis

To analyze the success, we selected three parameters: number of dead plants, the height of the plant and the diameter as data of horizontal volume growth. In order to compare diameter and high growth (dependent variables) for each of three species plants between treatment, we performed the analysis using a repeated-measures analysis of covariance (RM-ANOVA), with the repeated measure “day”. Data were examined for homogeneity of variances (Levene’s test, p > 0.05) and for normality of the variables (Shapiro–Wilk test). Multiple comparisons were made among treatments following a post hoc Tukey HSD procedure in all significant RM-ANOVA tests. Finally, we examined the relationships between mortality by species between treatment using a contingency table. Significance was determined by Fisher’s exact test to identify correlations within small data sets. All statistical analysis was completed using R statistical language (R Core program).

2.3. Colonisation of HDCL by Roots

2.3.1. Study Sites and Experimental Design

In these recent years, we performed some research that shows the capacity of a plant root system to colonize HDCL. We tested helophytes and riverside shrubs and trees, all function, but clearly, helophytes have faster growth. In this step of the experiment, we want to certify that a plant can grow faster in a coir log than in a natural environment. The experiment set was carried out in 3 different environments.
In Aquanea’s plant nursery, in Terrassa (Barcelona), we planted helophytes of the same side and age in two different substrates in coir logs (HDCL) and in soil subtract specially prepared to easily grow the plants (Figure 3).
A special planter area was built, and six wetland native species (Carex vulpina L., Carex pendula L., Iris pseudacorus L., Phragmites australis L., Scirpus holoschoenus L. and Juncus inflexus L.) were planted in a build size of 12 m × 0.8 m 125 × 1 m (length × width × height). The granulomere composition was gravel sands, a low proportion of fines. The distance between specimens was 20 cm, and 240 specimens were planted.
On the same day, we also planted some HDCL in a special pool semi-submerged in water. The vegetated fiber roll model was selected as it contains four of the six species (Carex vulpina, Iris pseudocorus, Scirpus holoschoenus and Juncus inflexus). In HDCL, helophytes were planted only in a line so that the distance between specimens was 20 cm.
For the third study, we selected two natural well-conserved environment areas where we removed some natural exemplars of the same helophytes selected for plants in the nursery. Two areas were selected in Natural Park Aiguamolls de l’Empordà (Girona).

2.3.2. Sampling Design and Data Collection

To analyze the root growth capacity and to enable comparisons between environments, several variables were taken: stem diameter, aerial height, aerial width, the root system’s depth, the root system’s width and the root system’s volume.
  • Soil planter. Sampling was carried out monthly over six months. We extracted 6 specimens of each species each month after taking aerial measures (stem diameter, aerial height, aerial width);
  • Vegetated coir fiber rolls (HDCL). Due to the characteristics of the fiber rolls, 3 specimens of the Carex vulpina, Iris pseudocorus, Scirpus holoschoenus and Juncus inflexus were measured and extracted every two months. When the plants are rooted to the fibers of the fiber roll, it is difficult to extract the specimens. The roots entangle with the fibers, and it is necessary to disassemble most of the fiber roll, as it was also difficult to distinguish them by eye. As some species have more than three specimens of species in the FR-N1 fiber roll, the selection of the specimens was achieved at random. The same measurements as in the soil planter were made;
  • Natural specimens. Three individuals of each six species were extracted in one single sampling in a natural area. Carex vulpina, Iris pseudocorus and Juncus inflexus were extracted in Castelló d’Empúries, Scirpus holoschoenus, Carex pendula and Phragmites australis were extracted from Aiguamolls de l’Empordà Natural Park.

2.3.3. Data Calculation and Statistical Analysis

From recollected data, four indexes were calculated, which indicate the helophytes’ stability and solidity: relative stability index (S = root system’s depth/aerial height), relative solidity index (s = root system’s width/aerial width), root system stability (R = Relative stability ∗ relative solidity) and global stability (P = Relative stability ∗ relative solidity2).
We calculated the differences between the 4 roots growth index mentioned for each species and treatment using the one-way ANOVA statistical test. Multiple comparisons were made among treatments following a post hoc Tukey HSD procedure in all significant ANOVA tests. In species that could only be measured in two environments, Welch’s t-test was calculated. We applied the Shapiro test to observe if the indexes followed a normal distribution. All statistical analysis was completed using R statistical language.

2.4. Success of Crib Wall Soil Bioengineering Works with Different Characteristics and Scenarios Using HDCL

2.4.1. Study Sites and Experimental Design

For compliment of these objectives, we included a set of works that involve crib wall techniques carried out in the Mediterranean area in different locations throughout Catalonia (Table 3). We constructed a list of all the works that involve crib walls that we performed in the province of Barcelona and Girona. The crib walls selected should be more than 5 m long.

2.4.2. Sampling Design and Data Collection

We visited all works on site to observe their naturalization between 2020 and 2021. Naturalized: when a crib wall appears completely covered by vegetation, just a detailed observation shows the original structure. We also observed whether holes and the origins were visible: all are by water income in the fascine areas.

3. Results

(A)
Improvement of HDCL resistance for hydro-meteorological hazards.
All of the jobs visited show a good quality: the HDCL vegetated had vegetation in all lengths, the roll maintains the volume, so there were no holes due to fibers being dragged away. The biggest storm event detected was in Sant Quirze, where 4.18 m/s velocity and 195.96 N/m2 shear stress was achieved successfully, although, during the flooding, gabions in the same area of 900 kg/m were moved by water (Table 4). The resistance of fiber rolls in the studied works depends more on the quality of the implantation than natural impacts. Although during the control time, there were no situations with tangential stress levels in any performance, and a limit situation was not observed. The fibers did not move due to the force of the water in any case, and the structure was maintained.
(B)
Effects of HDCL on the growth and survival of plants.
Each species has shown different behaviors in the aerial growth variables concerning the treatments (Table 5). Lavandula angustifolia shows significant differences in diameter (Figure 4) (F(2,102) = 4.09, p < 0.05) and close to significance in height (Figure 5) (F(2,102) = 2.97, p < 0.1) between treatments. The posthoc test indicates significant differences (p < 0.05) between the treatment of two lines and the treatment of one line with the control. Despite differences in growth of more than 5 cm in Viburnum tinus with a positive trend in all treatments, the ANOVA model results in close to significance (F(2,133) = 2.95, p < 0.1) in diameter. In contrast, growth in height has an overall negative trend for treatments, with significant global differences (F(2,133) = 3.06, p < 0.05) since the treatment of a single row obtained the worst diameter, although it is not significant in posthoc contrast (p < 0.1). Regarding the species Pistacia lentiscus, the two dependent variables of aerial growth showed differences between treatments; (F(2,137) = 4.52, p < 0.05) for the diameter and (F(2,137) = 7.12, p < 0.05) for the height (more than 8 cm). In the Tukey test, the two variables show the effect that two HDCL lines have on aerial growth in both diameters (p < 0.05) and height (p < 0.05) concerning control. There are also differences in height between two lines and one (p < 0.05) with more than 6 cm difference.
In terms of mortality analysis, 60% of all species’ analysis is concentrated in the control, 32% in a fiber roll one line and the remaining 8% with two lines. However, Fisher’s test shows only a trend in significance (p = 0.08), so it cannot be completely ruled out that fiber rolls do not have an effect on plant survival.
(C)
Colonization of HDCL by the roots.
The results of the ANOVAs show that, for the four species analyzed, only the relative stability index (S) is significant only for the species Iris pseudacorus (F(2,36) = 4.04, p < 0.05) and Carex vulpine (F(2,36) = 26.06, p < 0.05) (Table 6). The post hoc analysis shows that these differences are attributed to the species Iris pseudacorus between controlled environment and plants that grow in a wild environment (p < 0.05). For Carex vulpina species, these differences also occur between the wild environment and vegetated fiber (p < 0.05).
For the species Scirpus holoschoenus and Carex pendula, the analysis of the t-test shows as significant, and therefore, it can be stated that the stability index is different for the nursery group concerning the group of the wild environment. Carex pendula also show significant differences in R (root system stability) and P (global stability).
(D)
The success of crib wall soil bioengineering jobs with different characteristics and scenarios with the use of HDCL.
We analyzed the status of 23 works, and all were stabilized (Table 7). Naturalized is defined as when a crib wall looks vegetated; just a detailed observation shows the original structure. Commonly all the crib walls works became naturalized in five years. Nevertheless, in the CB fascine, works sometimes take longer. We only found holes in the CB fascine systems. We never observed any substantial damage.

4. Discussion

The crib wall soil and water bioengineering techniques are an excellent way to stabilize river slopes and landslide stabilization in the Mediterranean area. We observed that when using HDCL, this technic takes five years to become naturalized (fully vegetated), and longer if we use fascines.
The results of the work performed show that HDCL helps the plants to grow due to the capacity of water held. This capacity is not affected due to arid conditions. The plants observed growing show positive effects of the presence of coconut fiber rolls in all the controlled variables. The fact that the planting line with coconut fiber rolls on both banks was where fewer plants died, where more developed and where more flowers produced lavender could mean that the presence of coconut fiber rolls HDCL has a positive effect on vegetation. An interesting fact to finish the observations of this experiment would be the determination of the biomass of the plants, both of the aerial part and of the root system and, additionally, a qualitative study of the morphology of the roots by checking if there are differences in adaptation to water stress between the plants of the different planting lines (Control, F1, F2). On the one hand, it was observed that the species that best responded to the presence of coconut fiber was the mastic (Pistacia lentiscus), and the species that was less affected by the presence/absence of fiber rolls of coconut was the ivory (Viburnum tinus).
The data of root growth show that there is no difference in the root development between wild, cultivated or HDCL. Therefore, the log can become a suitable substrate for plants at a time that has mechanical properties. It would be exciting to know if this material can increase biodiversity in future research. It is also essential to highlight that the root system’s structure index for helophytes is between good and very good, which confirms these species have a good root system development. In this respect, it can be emphasized that, on the contrary, for containers or pots, vegetated fiber rolls allow implementing well-developed plants in natural areas. The indexes of relative stability are approximately 1, which are not very high, but considering that the aerial part is flexible and does not offer the same resistance, we may consider it a good result. The same conclusions apply to the potential stability index. On the other hand, vegetated fiber rolls are closer to an ideal environment than a wild environment, achieving a good root system development of the plants, confirming it is a good system for introducing helophytes in natural areas.
Good resistance of vegetated fiber rolls was observed in restored areas, where 4.18 m/s velocity was achieved successfully, although they were not installed in dynamical areas. The resistance of fiber rolls in the studied works depends more on the implantation quality than natural impacts, basically in the way to fix the rolls in the grown while the roots cannot be active in anchoring, such as in Anoia River.
The results show that the use of high-density coir logs (HDCL) has some advantages: stability against environmental changes, stability against flooding, plant grow and substrate capacity. All the visited crib walls were stable and successfully vegetated, but it is a fact that the ones with fascines have holes that can put the system at risk. The stability against environmental changes is due to the natural capacity of the fiber and the manufacturing of coir logs in the appropriate way (density). We cannot see any damage in the product on practical works installation of vegetated HDCL; no uptake of fiber was observed.
Although we have not conducted specific research on water retention by fascine, in this case, we detected two variables that make this technique less stable: fascine is made of material from the area, so they never have the same density. The density is not homogeneous. They are usually made from live branches, and we immediately notice a 20% reduction in diameter. Finally, the level of degradation of bundles in the Mediterranean area is very high. The level of coir fiber degradation is much lower than root growth. The density of the fiber roll makes that the colonization of the fiber structure by the plant is performed, in fact, by outstanding roots.
The force required to break a root increases linearly with increasing root diameter, but tensile strength is calculated per unit area. Therefore, smaller roots are stronger per unit area than large roots, decreasing root tensile strength with increasing root diameter [11]. Thus, fibers help to create a more resistant live structure. For the external stability analysis of such walls, the analysis can be performed as for other gravity retaining walls by assuming it is a monolithic construction, considering the composite body as a whole (Monolithic theory [12]) [1]. No articles discussing this study subject were found.
The success of naturalization of the crib wall after the visit of the different works performed are:
  • The large density of plants; the crib wall is a hard box that is difficult to replant, so mortality of 20–40% is normal and does not affect the final success;
  • It is essential to plant a significant diversity of species with the idea that each species have a particular adaptation capacity to the different conditions that the crib wall creates and increase success. Plant diversity is key to maintaining productive vegetation [13];
  • Fascines in the Mediterranean cannot guarantee that water will not enter into the structure when daily variation in humidity and temperature;
  • The introduction of rainwater in the system, but well-controlled, reduces the time of naturalization.

Author Contributions

Conceptualization, A.S.; methodology, A.S., E.P., B.M.-F., G.S.S., I.R., A.L.P. and C.U.; software, E.P.; validation, E.P.; formal analysis, A.S. and A.L.P.; investigation, A.S., E.P., B.M.-F., G.S.S., I.R. and A.L.P., resources, A.S., E.P., B.M.-F., G.S.S., I.R., A.L.P. and C.U.; data curation, A.S. and E.P.; writing—original draft preparation, A.S. and E.P.; writing—review and editing, A.S., E.P. and A.L.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research was partially funded by OPEn-air laboRAtories for Nature baseD solutions to Manage environmental risks (OPERANDUM).

Institutional Review Board

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

To our companions of Naturalea team: Salut Ribera, Xavi Sorolla, Mireia Gambús Teresa Navas and Eva Celda.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

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Figure 1. Scheme of a traditional crib wall simple (left) or double or Krainer (right).
Figure 1. Scheme of a traditional crib wall simple (left) or double or Krainer (right).
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Figure 2. Experiment design to test the effects of HDCL on growth and survival of plants. Brown: Viburnum tinnus; orange: Lavandula angustifolia; green: Pistacia lentiscus.
Figure 2. Experiment design to test the effects of HDCL on growth and survival of plants. Brown: Viburnum tinnus; orange: Lavandula angustifolia; green: Pistacia lentiscus.
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Figure 3. Planter and a pool where helophytes were planted in Aquanea’s plant nursery.
Figure 3. Planter and a pool where helophytes were planted in Aquanea’s plant nursery.
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Figure 4. Plant diameter growth and HDCL influence. Subject Results. Effects of HDCL on the growth and survival of plants.
Figure 4. Plant diameter growth and HDCL influence. Subject Results. Effects of HDCL on the growth and survival of plants.
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Figure 5. Plant height growth and HDCL influence. Subject Results. Effects of HDCL on the growth and survival of plants.
Figure 5. Plant height growth and HDCL influence. Subject Results. Effects of HDCL on the growth and survival of plants.
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Table 1. Volume variation in the different woods according to the water content [5].
Table 1. Volume variation in the different woods according to the water content [5].
% Volumetric Concentration% Volumetric Concentration Coefficient
Castanea sativa8.70.396
Fraxinus excelsior13.310.55
Pinus halepensis14.130.45
Pinus pinsaster14.630.34
Pinus sylvestris15.620.34
Platanus x hispanica16.420.61
Quercus cerrioide13.240.45
Table 2. Data and characteristics of the interventions. Improving HDCL for resistance to hydro-meteorological hazards.
Table 2. Data and characteristics of the interventions. Improving HDCL for resistance to hydro-meteorological hazards.
PlaceDate of InstallationLineal Meters of Coir Roll InstaletaedVegetation Planted Present
Fluvià river, Pont de les mores (Olot)May 200770Carex pendula, absence of Iris pseudacorus and Scirpus holoschoenus
Anoia River, Sant Esteve de Ses Rovires200750It was not possible to find the fiber roll.
Riu Mogent, Llinars del Vallès200340There are no Scirpus holoschoenus or Carex vulpina. Iris pseudacorus occupies the entire fiber roll.
Fluvià River, Besalú200840There are new species in the fiber roll: Typha sp. The fiber roll is now composed of Iris pseudacorus, Carex pendula, Scirpus holoschoenus and Carex vulpina.
Congost River, Granollers200850There are no Carex vulpina, and Scirpus holochoenus is scarce. The main abundance is of Iris pseudacorus, with the presence of Scripus holoschoenus and Lythrum.
Besós River, Montcada i Reixac200120There is Typha sp. and Urtica sp. The main abundance is of Iris pseudacorus, with less abundance of Scripus holoschoenus and Carex pendula.
Torrent de Vallcorba, Sant Quirze del Vallès200950The prevalent species is Iris pseudacorus, followed by Carex vulpina and Scirpus holoschoenus.
Table 3. Data and characteristics of the selected Crib wall interventions.
Table 3. Data and characteristics of the selected Crib wall interventions.
Works TypeLocationFoundationMain StructureWood SpicesDate of Construction
Sant Cugat Stream Can CabassaE. KRAINER E.SIMPLEFLUVIALtubular flexible gabionHDFLCastanea sativaNovember 2016
Palausolità i Plegamans Riera SentmenatE. KRAINERFLUVIALfascinefascineRobinia pseudoacaciaDecember 2011
Cànoves Riera de CànovesE. KRAINERFLUVIALfascinefascineCastanea sativaMarch 2016
Santa Eulalia de Ronçana.River Tenes E. KRAINERFLUVIALtubular flexible gabionHDFLCastanea sativaOctober/December 2011
Santa Eulalia de Ronçana.River Tenes E. KRAINERFLUVIALtubular flexible gabiontubular flexible gabionCastanea sativaDecember 2016
Sentmenat Foodpath slope stabilizationE. KRAINERSLOPENOfascineCastanea sativaNovember 2010
La Garriga. River CongostE. KRAINERFLUVIALFEIXINA VIVAfascineCastanea sativaMarch 2010
Vacarisses-Urban slope stabilizationE. KRAINERSLOPENO HDFLCastanea sativaApril 2021
Roqes Blanques. Park slope stabilizationE. KRAINERSLOPENO HDFLCastanea sativaJune 2017
Garrotxa Natural Parc slope stabilizationE.SIMPLESLOPENO HDFLCastanea sativaDecember 2020
Garrotxa Natural Parc slope stabilizationE.SIMPLESLOPENO HDFLCastanea sativaDecember 2020
Roses Beach slope stabilizationE. KRAINERSEAtubular flexible gabionHDFLCastanea sativaFebruary/March 2018
Valldoreig Castle slope stabilizationE.SIMPLESLOPENO HDFLCastanea sativaDecember 2019
Montmeló eschool slope estabilizationE.SIMPLESLOPENO HDFLCastanea sativaJanuary 2019
Serralada Marina Natural Parc.Tiana. Slope stabilizationE.SIMPLESLOPENO HDFLCastanea sativaMarch 2019
Barcelona Stream Argentinina.Urban area.E.SIMPLESLOPENO tubular flexible gabionCastanea sativaDecember 2019
Begur Stream SaltseseuguesE.SIMPLEFLUVIALtubular flexible gabionHDFLPinus halepensis & Castanea sativaDecember 2020
Montornès del Vallès. River Tenes E. KRAINERFLUVIALHDFLHDFLCastanea sativaMay 2020
Castellar del Vallès River Ripoll, foodpath slope stabilizationE.SIMPLESLOPENOfascineCastanea sativaMarch 2020
Sant Pere de Ribes Millora del primer tram del camí de PuigmoltóE.SIMPLESLOPENO HDFLCastanea sativaFebruary 2020
Sant Antoni de Vilamajor. Stream VilamajorE. KRAINERFLUVIALtubular flexible gabiontubular flexible gabionCastanea sativaMay 2021
Cardedeu. River VallfornersE. KRAINERFLUVIALtubular flexible gabionHDFLCastanea sativaMay 2015
Tarroja de Segarra. River SióE. KRAINERFLUVIALfascinefascineCastanea sativaMarch 2015
Sant Hilari SacalmE. KRAINERFLUVIALfascinefascinePinus sylvestris & Castanea sativaSeptember 2008
Barcelona. Park GuellE. SIMPLESLOPENOfascineCastanea sativaApril–July 2018
Table 4. Hydraulic characteristics of the hydro-meteorological hazards that have affected the executed works.
Table 4. Hydraulic characteristics of the hydro-meteorological hazards that have affected the executed works.
PlaceHDCL StatusDatePeak Flow (m3/s)Velocity (m/s)Shear Stress (N/m2)
Fluvià River, Pont de les mores (Olot)Vegetated and maintained volume28/12/200830.23.7420.28
14/04/200713.271.61
01/02/200911.391.38
Anoia River, Sant Esteve de Ses RoviresVegetated and maintained volume10/10/201013.722.889.54
10/06/20102.840.59
16/03/20111.800.38
Riu Mogent, Llinars del VallèsVegetated and maintained volume15/03/201163.6842.6979.08
13/09/200615.610.65
27/02/200311.830.50
Fluvià River, BesalúVegetated and maintained volume28/12/200830.721.2930.43
14/04/200713.270.55
01/02/200911.390.48
Congost River, GranollersVegetated and maintained volume15/03/201157.381.9345.08
02/11/20089.620.62
13/02/20115.930.19
Besós River, Montcada i ReixacVegetated and maintained volume27/02/200386.51.3526.47
13/09/200682.531.29
04/12/200354.980.86
Torrent de Vallcorba, Sant Quirze del VallèsVegetated and maintained volume17/09/201042.434.18195.96
Table 5. Measurement results of structure of helophytic roots growing in HDFL fibers in three different environments. (Mean and Standard Error).
Table 5. Measurement results of structure of helophytic roots growing in HDFL fibers in three different environments. (Mean and Standard Error).
Wild EnvironmentControlled EnvironmentVegetated Coconut
Stem diameter (mm)8.9 ± 1.40.5 ± 0.00.5 ± 0.1
Aerial height (cm)100.7 ± 9.839.5 ± 1.258.0 ± 2.0
Aerial width (cm)71.4 ± 19.726.1 ± 1.337.7 ± 2.5
Root system’s depth (cm)41.2 ± 2.7234.3 ± 1.149.3 ± 2.4
Root system’s width (cm)29.3 ± 2.4615.7 ± 0.819.6 ± 1.4
Root system’s volume (mL)1260.5 ± 376.7115.2 ± 7.2216.9 ± 15.6
Table 6. ANOVA and t-test results for each of the indexes. Subject Results. Colonization of HDCL by the roots.
Table 6. ANOVA and t-test results for each of the indexes. Subject Results. Colonization of HDCL by the roots.
S: Relative Stability Indexs: Relative Solidity IndexR: Root System StabilityP: Global Stability
Juncus inflexus
F2.2081.3780.7991.09
P effect0.1250.2650.4580.347
Iris pseudacorus
F4.41.392.41.4
P effect<0.050.260.100.25
Carex vulpina
F26.060.932.740.38
P effect<0.050.4<0.10.68
Scirpus Holoschoenus
t2.760.210.89−0.12
P effect<0.050.830.380.91
Phragmites australis
F0.340.80.9320.616
P effect0.550.370.340.43
Carex pendula
t3.41.852.912.64
P effect<0.050.14<0.05<0.05
Table 7. Works with the crib wall characteristics and the results of the visits.
Table 7. Works with the crib wall characteristics and the results of the visits.
WorksType Soil Stability SystemYear of ExecutionObservationAntiquity
1Sant Cugat Stream Can CabassaE. KRAINER/E.SIMPLEHDFL2016naturalized5
2Palausolità i Plegamans Riera SentmenatE. KRAINERfascine2011naturalized10
3Cànoves Riera de CànovesE. KRAINERfascine2016stabilized but week in naturalization due Robinia pseudoacacia colonization due proximity urban robinia plantation5
4Santa Eulalia de Ronçana.River Tenes E. KRAINERHDFL2011naturalized10
5Santa Eulalia de Ronçana.River Tenes E. KRAINERtubular flexible gabion2016stabilized, very succes in flood resistence, but less succes for plants5
6Sentmenat Foodpath slope stabilizationE. KRAINERfascine2010stabilized and close to naturalization6
7La Garriga. River CongostE. KRAINERfascine2011naturalized but with risc during the process (finally success) due that fascine diameters variation wholets water enter in the Krainer and take out soil.10
8Vacarisses-Urban slope stabilizationE. KRAINERHDFL2021Just finished
9Roqes Blanques. Park slope stabilizationE. KRAINERHDFL2017stabilized and close to naturalization, good management of stormwater. Maintenance4
10Garrotxa Natural Parc slope stabilizationE.SIMPLEHDFL2020Recently finished, but good progress
11Roses Beach slope stabilizationE. KRAINERHDFL2018Stabilized and close to naturalization, good intrusion salinity protection thangs fibers3
12Montmeló eschool slope estabilizationE.SIMPLEHDFL2019stabilized, garden aspect, good management of stormwater. 2
13Serralada Marina Natural Parc.Tiana. Slope stabilizationE.SIMPLEHDFL2019Stabilized but poorly vegetated, the progress is good but is a very dry area2
14Barcelona Stream Argentinina.Urban area.E.SIMPLEtubular flexible gabion2020Recently finished, d, in correct progress
15Begur Stream SaltseseuguesE.SIMPLEHDFL2020Recently finished, but good progress
16Montornès del Vallès. River Tenes E. KRAINERHDFL2021Recently finished, in correct progress
17Castellar del Vallès River Ripoll, foodpath slope stabilizationE.SIMPLEfascine2021Recently finished, in correct progress
18Sant Pere de Ribes Millora del primer tram del camí de PuigmoltóE.SIMPLEHDFL2020Recently finished, in correct progress
19Sant Antoni de Vilamajor. Stream VilamajorE. KRAINERtubular flexible gabion2021Just finished
20Cardedeu. River VallfornersE. KRAINERHDFL2015naturalized6
21Tarroja de Segarra. River SióE. KRAINERfascine2015naturalized6
22Sant Hilari SacalmE. KRAINERfascine2008naturalized13
23Barcelona. Park GuellE. SIMPLEfascine2018naturalized. Fast due mantenance3
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Sorolla, A.; Piera, E.; Mota-Freixas, B.; Sorolla Salvans, G.; Rueda, I.; Lochner Prats, A.; Unzeta, C. Improvement of the Plantation Success in a Crib Wall in a Mediterranean Hydro-Meteorological Risks Scenario—Practical Results. Sustainability 2021, 13, 11785. https://doi.org/10.3390/su132111785

AMA Style

Sorolla A, Piera E, Mota-Freixas B, Sorolla Salvans G, Rueda I, Lochner Prats A, Unzeta C. Improvement of the Plantation Success in a Crib Wall in a Mediterranean Hydro-Meteorological Risks Scenario—Practical Results. Sustainability. 2021; 13(21):11785. https://doi.org/10.3390/su132111785

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Sorolla, Albert, Eduard Piera, Bet Mota-Freixas, Gina Sorolla Salvans, Inma Rueda, Adrian Lochner Prats, and Clara Unzeta. 2021. "Improvement of the Plantation Success in a Crib Wall in a Mediterranean Hydro-Meteorological Risks Scenario—Practical Results" Sustainability 13, no. 21: 11785. https://doi.org/10.3390/su132111785

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