Use of alternative containers for promoting deep rooting of native forest species used for dryland restoration: the case of Acacia caven

Fuente, Luz María de la; Ovalle, Juan F.; Arellano, Eduardo C.; Ginocchio, Rosanna

doi:10.3832/ifor2101-010

Cited by 11 publications

(9 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The effect of increasing container volume on seedling morphology development is widely documented (Prieto-Ruiz et al 2007, Gil & Díaz 2016. However, the effect of increased container depth on seedling morphology may have different responses according to species characteristics (Chirino et al 2005, Kostopoulou et al 2011, De la Fuente et al 2017. In this study, a deep container was used to produce seedlings with a longer taproot and a higher DWR/ DWS ratio to favour not only deep root system development, but also the rapid colonization of deeper soil layers before the first summer.…”

Section: Effect Of Deep Container On the Morphological Characteristicmentioning

confidence: 97%

“…Previous studies that employed containers with similar depths in Quercus coccifera, Q. ilex (Chirino et al 2005) and Q. suber (Chirino et al 2008) reported the production of seedlings with no significant differences in height and basal diameter compared to those grown in standard containers. This also allowed to produce seedlings destined to dry ecosystems with a higher DWR/DWS ratio in the seedlings grown in deep containers (Chirino et al 2005, 2008, Mariotti et al 2015b, which favours better root growth and greater resistance to Mediterranean water stress characteristics (Pemán et al 2006, De la Fuente et al 2017. Other studies that have employed deep containers produced seedlings with a longer taproot (Trinidad et al 2015) and a higher stem height (Mariotti et al 2015c).…”

Section: Effect Of Deep Container On the Morphological Characteristicmentioning

confidence: 99%

“…Other studies that have employed deep containers produced seedlings with a longer taproot (Trinidad et al 2015) and a higher stem height (Mariotti et al 2015c). However, effects on stem height, diameter and other morphological characteristics have not always been observed (Trinidad et al 2015, De la Fuente et al 2017.…”

Section: Effect Of Deep Container On the Morphological Characteristicmentioning

confidence: 99%

See 2 more Smart Citations

Using field and nursery treatments to establish Quercus suber seedlings in Mediterranean degraded shrubland

Muñoz-Rengifo¹,

Chirino²,

Cerdán³

et al. 2020

iForest

View full text Add to dashboard Cite

Biogeosciences and Forestry Biogeosciences and Forestry Using field and nursery treatments to establish Quercus suber seedlings in Mediterranean degraded shrubland Julio Muñoz-Rengifo (1-2) , Esteban Chirino (3) , Vicent Cerdán (4) , Jesús Martínez (4) , Osvaldo Fosado (5) , Alberto Vilagrosa (6) Cork oak (Quercus suber L.) is a suitable species for restoring Mediterranean ecosystems due to its capacity to resprout after wildfires and its economic importance for the use of cork. Several studies have focused on improving the seedling quality and abiotic conditions at the outplanting site to favour the field performance of Q. suber, however, most studies have been conducted by independently testing treatments. The aim of this study was to assess the combined effect of three techniques that focused on reforestation success with Q. suber in Mediterranean degraded shrubland: (i) a nursery technique to improve root system development, such as the use of deep containers to develop a longer tap root, combined with two field techniques such as (ii) the use of tree shelters to diminish solar radiation stress, and (iii) shrubland treatments to reduce competition for soil water and nutrients. For this purpose, 1-yearold Q. suber seedlings were grown in two containers types: a shallow container (CCS-18) and a deep container (CCL-30). Seedlings were established in a degraded shrubland at three experimental sites in the Calderona mountain range of Castellón, Spain. A factorial design was combined based on container type (CCS-18 and CCL-30), shrubland management (undisturbed shrubland and cleared shrubland in strips) and tree shelters (vegetable fibre tree shelters and no tree shelters). After 2 years of monitoring, the outplanting results indicated that using: (i) a deep container produced a longer taproot, but did not favour better survival or better field performance of seedlings; (ii) tree shelters improved the microweather conditions around seedlings, particularly by reducing excess incoming solar radiation; (iii) cleared shrubland strips reduced competition for soil water by favouring a higher water potential, better maximum photochemical PSII efficiency and higher survival rates for the seedlings established into cleared sites. The results indicate that the cleared shrubland treatment effects overlap the effects of using deep containers and tree shelters. This, in turn, reveals that shrubland clearing is the most suitable technique for favouring the introduction of a resprouter species like Q. suber into ecosystems characterized by predominantly degraded shrublands.

show abstract

Section: Effect Of Deep Container On the Morphological Characteristicmentioning

confidence: 97%

Section: Effect Of Deep Container On the Morphological Characteristicmentioning

confidence: 99%

Section: Effect Of Deep Container On the Morphological Characteristicmentioning

confidence: 99%

See 1 more Smart Citation

Using field and nursery treatments to establish Quercus suber seedlings in Mediterranean degraded shrubland

Muñoz-Rengifo¹,

Chirino²,

Cerdán³

et al. 2020

iForest

View full text Add to dashboard Cite

show abstract

“…Various ecotechnological treatments could help to dampen or reduce competition with Stipa and tilt the net balance of the grass-shrub interaction toward a neutral or positive interaction. For example, techniques that promote niche differentiation between shrubs and grasses, such as the use of long containers for seedling production to promote deeper rooting (de la Fuente et al, 2017), combined with deep planting (Oliet et al, 2012) and/or deep preparation of the soil for planting (Chirino et al, 2009), can help to overcome the initial overlap of rooting depths earlier, accelerating one of the effects of the natural ontogeny process on slow-growing tall shrubs.…”

Section: Applications To Restorationmentioning

confidence: 99%

Interacting water, nutrients, and shrub age control steppe grass‐on‐shrub competition: Implications for restoration

Morcillo

Bautista

2022

Ecosphere

View full text Add to dashboard Cite

Understanding the factors that control grass-shrub interactions and coexistence is critical to the design of dryland management and restoration strategies. Using Stipa tenacissima tussocks as adult neighbor and Olea europaea var. sylvestris as target woody species, we performed a 5-year-long, large-scale manipulative experiment to investigate the independent and combined effects of water and nutrient availability, and the modulating effects of O. europaea ontogeny on the net outcome of grass-shrub interaction. At two contrasting dryland sites, we conducted experimental plantings of Olea seedlings on two microsites: contiguous to a Stipa tussock (Stipa microsite) and on the intertussock bare-soil areas (Open microsite), and manipulated resource availability by combining nutrient and water addition. The experiment followed a full factorial design, with all treatment combinations applied at each site. We monitored survival, height, and stem basal diameter of Olea individuals over a study period of 5 years. All across the wide range of conditions considered, negative effects of Stipa on Olea largely prevailed during the first 2 years after the plantation. We found that competition was stronger in the drier steppe, where extra inputs of water favored neutral interactions. Conversely, nutrient addition increased competition strength, particularly when combined with water inputs, pointing to the contrasting role of different resources and the importance of interactions between them in the control of plant-plant interaction outcome. The competition effects of Stipa faded with time and gradually shifted to neutral interaction as Olea individuals aged. Our results are particularly relevant to guide restoration efforts in formerly wooded xeric grasslands and rangelands.

show abstract

“…Other studies conducted in arid, semi-arid, and dry tropical areas have proven the positive effect between root length and seedling survival after transplanting (Markesteijn and Poorter, 2009;León et al, 2011;Ovalle et al, 2015). De La Fuente et al (2017) pointed out that a seedling with a long taproot has adequate morphology and biomass distribution allowing it to colonize deep soil layers. These characteristics thus improve the physiological response of seedlings to water stress conditions (Chirino et al, 2008).…”

Section: Introductionmentioning

confidence: 97%

Physiological and biochemical responses of argan (Argania spinosa (L.)) seedlings from containers of different depths under water stress

ALI

HACHEMI

Moumni

et al. 2021

Not Bot Horti Agrobo

View full text Add to dashboard Cite

Plant species characteristic of arid and semi-arid zones, such as Argania spinosa (L.) Skeels, have a taproot that allows them to reach the soil horizons more quickly. Unfortunately, in the nursery, the containers of culture used for the production of seedlings do not support an excellent development of the root architecture that can be able to resist the shock of transplantation, in particular of the hydric stress. This study aimed to evaluate the physiological and biochemical behavior of Argania spinosa seedlings grown in containers of different depths under water stress. An experiment was conducted with 90 seedlings from the different containers (P1 for depth of 16 cm, P2 for depth of 30 cm, and P3 for depth of 60 cm), and three watering treatments (well-watered 100% of field capacity, moderate stress with 50% of field capacity and severe stress with 25% of the field capacity). Our results showed that seedlings from the 16 cm container had lower values of water status. Malondialdehyde content, electrolyte leakage, hydrogen peroxide, and superoxide radical content gave higher values on seedlings from the shallow container. The benefits of increasing the container depth of nursery seedlings contribute to the improvement of physiological and biochemical responses of seedlings under water stress. To fully validate our findings, a long-term field study must be conducted.

show abstract

Use of alternative containers for promoting deep rooting of native forest species used for dryland restoration: the case of Acacia caven

Cited by 11 publications

References 42 publications

Using field and nursery treatments to establish Quercus suber seedlings in Mediterranean degraded shrubland

Using field and nursery treatments to establish Quercus suber seedlings in Mediterranean degraded shrubland

Interacting water, nutrients, and shrub age control steppe grass‐on‐shrub competition: Implications for restoration

Physiological and biochemical responses of argan (Argania spinosa (L.)) seedlings from containers of different depths under water stress

Contact Info

Product

Resources

About