Characterizing spatial structure of Abies marocana forest through point pattern analysis

Ben-Said, Mariem; Ghallab, Abdelilah; Lamrhari, Hajar; Carreira, José A.; Linares, Juan Carlos; Taïqui, Lahcen

doi:10.5424/fs/2020292-16754

Cited by 15 publications

(12 citation statements)

References 47 publications

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“…The resulting canopy disturbance periods were 1927-1950, 1952-1962, 1967-1977, 1981-1993, and 1994-2005. To quantify the horizontal patterns of trees and canopy disturbances across the 1-ha site, we used point pattern analysis techniques (Baddeley et al, 2015). Specifically, we used the pair correlation function g(r), which is a variation of Ripley's K function, the two most commonly used spatial descriptors in ecology (Velázquez et al, 2016;Ben-Said et al, 2020Cannon et al, 2022). The pair correlation function uses discrete distance annuli (Wiegand & Moloney, 2004) to test the density of observed points at multiple distances (r) against the expected density at distance (r).…”

Section: Methodsmentioning

confidence: 99%

Spatial patterns of stand structure and canopy disturbance in a fire‐maintainedPinus palustriswoodland

Phillips

Goode

Hart

2022

Applied Vegetation Science

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Question Stand structural complexity is increasingly valued by forest managers to promote resilience, and quantitative spatial data from reference stands can help achieve these goals. We questioned how stand structural elements were spatially distributed across a Pinus palustris woodland. Specifically, we sought to quantify patterns of individual trees, tree clumps, openings, and canopy disturbance and examine spatial relationships between P. palustris saplings and P. palustris and Quercus spp. trees. Location Fall Line Hills, Alabama, USA (32°56′12′′ N, 87°25′37′′ W). Methods We recorded tree species, diameter, age, and location of all trees, and reconstructed canopy disturbance events across a 1‐ha site in a P. palustris woodland. We used global point pattern analysis (g(r) function) and a local spatial classification method (individuals, clumps, and openings) to examine the distribution of stand structural elements and canopy disturbance. Results Trees were generally clustered by taxa and diameter. Pinus palustris saplings exhibited no spatial relationship with P. palustris trees, but were clustered around Quercus trees at variable distances. Approximately half of the trees in the stand occurred in large clumps, and ca. 10% of trees occurred as individuals that did not touch crowns with neighbors. For three of the five disturbance periods, canopy disturbances were clustered in space at various distances. Conclusions Spatial randomness and clustering of structural elements and canopy disturbance events were evident across the reference site. The spatial patterns of stand structure quantified here, in conjunction with data from other georeferenced studies, can be used to develop silvicultural guidelines to enhance structural complexity and promote resilience.

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Section: Methodsmentioning

confidence: 99%

Spatial patterns of stand structure and canopy disturbance in a fire‐maintainedPinus palustriswoodland

Phillips

Goode

Hart

2022

Applied Vegetation Science

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“…Nevertheless, in the absence of large plots, it is recommended to combine several small plots and their accuracy is improved using the HP null model instead of CSR in order to account for environmental heterogeneity and capture small-scale spatial structure (Carrer et al 2018). Hence, small size plots are largely used in replicated analysis (Riginos et al 2005;De Luis et al 2008;Comas et al 2009;Raventós et al, 2011;Petritan et al 2014Petritan et al , 2015Erfanifard and Stereńczak 2017;Ziegler et al 2017;Erfanifard et al 2019;Ben-Said et al 2020;Wang et al 2020a) where many small plots are sampled over a large study area then combined in one average function.…”

Section: Sample Plot Sizementioning

confidence: 99%

“…The sample size did not necessarily condition the number of individuals, but this number depends on the forest under investigation. For example, Ben-Said et al (2020) established a plot with 20 m of radius which contained 79 trees, while another plot with only 15 m of radius contained 98 trees. Moreover, Comas et al (2009) used circular plots with 20 m of radius that contained approximately 100 trees of pine resulting in plots ranging from 0.04 to 0.16 ha.…”

Section: Number Of Pattern Pointsmentioning

confidence: 99%

“…Thus, to deal with this problem, a combination between plot size and number of points seems to be a suitable alternative, that is, the sample size can be conditioned by the number of individuals involved. Despite being considered a small size sample, plots containing less than 50 points can be considered the first step especially in exploratory studies to make preliminary hypotheses for forests that have not been the subject of previous spatial pattern studies (Ben-Said et al 2020), as well as when sufficient equipment and financial or human resources are lacking. Thus, the choice of a sample size as a function of the number of individuals involved seems to be a trade-off between the minimum number required in SPPA and the difficulty of establishing large plots.…”

Section: Number Of Pattern Pointsmentioning

confidence: 99%

“…Studying spatial association between trees at both intra-and interspecific levels is important to reveal the existence of interactions and their types (Jia et al 2016). SPPA has been mostly carried out for woody species compared to herbaceous plants (but see Riginos et al 2005;De Luis et al 2008;Raventós et al 2010) and various mechanisms controlling species spatial patterns are currently investigated in temperate (Getzin et al 2006;Hao et al 2007;Wang et al 2010a;Zhang et al 2010Zhang et al , 2013Martínez et al 2013;Liu et al 2014;Yao et al 2016;Carrer et al 2018;Wang et al 2018;Szmyt and Tarasiuk 2018;Zhang et al 2020), tropical (Wiegand et al 2007a;Lan et al 2012;Miao et al 2018;Nguyen et al 2016;Cordero et al 2016;Ribeiro et al 2021, Nguyen et al 2018a and Mediterranean regions (Camarero et al 2005;De Luis et al 2008;Lingua et al 2008;Comas et al 2009;Raventós et al 2010;Garcia-Cervigon et al 2017;Abellanas and Pérez-Moreno 2018;Ben-Said et al 2020). Assuming the crucial role of biotic processes to be a driver of species spatial pattern, various environmental factors can be involved in structuring plant communities including water availability (Zheng et al 2017), soil nutrients (Riginos et al 2005;Zhao et al 2015), moisture (Fajardo et al 2006;…”

Section: Introductionmentioning

confidence: 99%

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Spatial point-pattern analysis as a powerful tool in identifying pattern-process relationships in plant ecology: an updated review

Ben-Said

2021

Ecol Process

Self Cite

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Background Ecological processes such as seedling establishment, biotic interactions, and mortality can leave footprints on species spatial structure that can be detectable through spatial point-pattern analysis (SPPA). Being widely used in plant ecology, SPPA is increasingly carried out to describe biotic interactions and interpret pattern-process relationships. However, some aspects are still subjected to a non-negligible debate such as required sample size (in terms of the number of points and plot area), the link between the low number of points and frequently observed random (or independent) patterns, and relating patterns to processes. In this paper, an overview of SPPA is given based on rich and updated literature providing guidance for ecologists (especially beginners) on summary statistics, uni-/bi-/multivariate analysis, unmarked/marked analysis, types of marks, etc. Some ambiguities in SPPA are also discussed. Results SPPA has a long history in plant ecology and is based on a large set of summary statistics aiming to describe species spatial patterns. Several mechanisms known to be responsible for species spatial patterns are actually investigated in different biomes and for different species. Natural processes, plant environmental conditions, and human intervention are interrelated and are key drivers of plant spatial distribution. In spite of being not recommended, small sample sizes are more common in SPPA. In some areas, periodic forest inventories and permanent plots are scarce although they are key tools for spatial data availability and plant dynamic monitoring. Conclusion The spatial position of plants is an interesting source of information that helps to make hypotheses about processes responsible for plant spatial structures. Despite the continuous progress of SPPA, some ambiguities require further clarifications.

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Cultural dimensions of forest conservation under global change: the case of relict Mediterranean fir forests

Seijo,

Linares,

Sánchez-Salguero

et al. 2023

Landsc Ecol

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Characterizing spatial structure of Abies marocana forest through point pattern analysis

Cited by 15 publications

References 47 publications

Spatial patterns of stand structure and canopy disturbance in a fire‐maintainedPinus palustriswoodland

Spatial patterns of stand structure and canopy disturbance in a fire‐maintainedPinus palustriswoodland

Spatial point-pattern analysis as a powerful tool in identifying pattern-process relationships in plant ecology: an updated review

Cultural dimensions of forest conservation under global change: the case of relict Mediterranean fir forests

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