Combined retention of large living and dead trees can improve provision of tree-related microhabitats in Central European montane forests

Spînu, Andreea Petronela; Asbeck, Thomas; Bauhus, Jürgen

doi:10.1007/s10342-022-01493-1

Cited by 9 publications

(9 citation statements)

References 79 publications

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“…North-facing slopes, with their more humid microclimate, favour tree cavity formation (Remm and Lõhmus, 2011) and epiphyte growth (Esseen and Ekström, 2023), potentially leading to an increased abundance of TreMs. However, the relationship between TreM numbers and northfacing slopes was not evident in mixed beech-spruce-fir forests (Asbeck et al, 2022). Hence, our findings suggest that the influence of slope exposure on TreMs depends on the local landscape context that determines the climatic conditions prevailing in the studied region.…”

Section: Effect Of Topographic Conditions On Tremsmentioning

confidence: 53%

“…Our study failed to reveal any relationship between TreM indices and the presence of canopy gaps and their characteristics. A previous study of mixed Norway spruce-European beech-silver fir forests showed that the TreM density increased with the percentage of canopy gaps (Frey et al, 2020), although this research was conducted in a managed forest, where certain ecological processes, including TreM formation, may be disrupted as a result of former tree removal (Asbeck et al, 2022). In natural European beech forests, canopy gaps, originating mostly from small-scale disturbances caused by strong winds or snowfall, lead to the accumulation of TreM-rich dead, wounded and damaged living trees (Lewandowski et al, 2021).…”

Section: Effect Of Canopy Gaps On Tremsmentioning

confidence: 93%

“…Secondary or previously managed forests have very much smaller numbers of snags and large living trees, resulting in the absence of certain TreM types Paillet et al, 2017). As a result, managed forests typically have fewer TreMs and do not have TreM profiles typical for ancient stands (Asbeck et al, 2022).…”

Section: Profile and Reference Values Of Tremsmentioning

confidence: 99%

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Spatial distribution of Tree-related Microhabitats in a primeval mountain forest: from natural patterns to landscape planning and forest management recommendations

Przepióra,

Lewandowski,

Ciach

2024

Preprint

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Tree-related Microhabitats (TreMs) are essential for sustaining forest biodiversity. Although TreMs represent ephemeral resources that are spread across the landscape, their spatial distribution within temperate forests remains poorly understood. To address this knowledge gap, we conducted a study on 90 sample plots (0.05 ha each) located in a primeval mountain European beech Fagus sylvatica-dominated forest (Bieszczady Mountains, Carpathians). We explored the TreM profile with its link to habitat characteristics and described the spatial distribution of TreM indices. We identified 61 TreM types, with a mean richness of 19.7 +-4.9 SD TreM types per plot, a mean density of 740.7 +-292.5 SD TreM-bearing trees ha-1 and a mean TreM diversity of 1.2 +-0.1 SD. The diameter and living status of trees (living vs dead standing tree) were correlated with TreM richness on an individual tree. The stand structure, i.e. density and/or basal area of living and/or dead standing trees, and topographic conditions, i.e. slope exposure, were correlated with the TreM richness, density and diversity recorded on a study plot. We found no relationship between TreM richness, density and diversity and the presence of canopy gaps, which indicates that the influence of small-scale disturbances on the TreM profile is limited. However, our analysis revealed a clustered spatial pattern of TreM indices, with TreM-rich habitat patches (hot-spots) covering ~20% of the forest. A moderate TreM richness, density and diversity dominated ~60% of the forest, while TreM-poor habitat patches (cold-spots) covered ~20%. Based on our findings, we advise the transfer of knowledge on the spatial distribution of TreMs from primeval to managed forests and advocate the '2:6:2' triad rule: to allocate 20% of forests as strictly protected areas, to dedicate 60% to low-intensity forest management with the retention of large living trees and all dead standing trees, and to use the remaining 20% for intensive timber production. To ensure the continuance of the majority of TreM types, ≥ 55 living trees ha-1 > 60 cm in diameter should be retained. Such an approach will maintain a rich and diverse TreM assemblage across a broad spatial scale, which in turn will support biodiversity conservation and ecosystem restoration in secondary or managed forests.

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Section: Effect Of Topographic Conditions On Tremsmentioning

confidence: 53%

Section: Effect Of Canopy Gaps On Tremsmentioning

confidence: 93%

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Spatial distribution of Tree-related Microhabitats in a primeval mountain forest: from natural patterns to landscape planning and forest management recommendations

Przepióra,

Lewandowski,

Ciach

2024

Preprint

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“…These structures have been reported to increase with tree diameter at breast height (DBH) and are often more abundant in broadleaved trees than in conifers and differ between dead and live trees (Paillet et al, 2017;Spinu et al, 2022) and in primary compared to managed forests (Asbeck, Kozák, et al, 2021). To our knowledge, this is the first structural complexity enhancement (SCE) experiment done in secondary spruce forests that also addressed the dynamics of TreMs.…”

Section: Introductionmentioning

confidence: 98%

“…These structures provide important habitats for forest‐dwelling species and are defined as “distinct, well delineated structures occurring on living or standing dead trees, that constitute a particular and essential substrate or life site for species or species communities during at least a part of their life cycle to develop, feed, shelter or breed” (Larrieu et al, 2018 ). These structures have been reported to increase with tree diameter at breast height (DBH) and are often more abundant in broadleaved trees than in conifers and differ between dead and live trees (Paillet et al, 2017 ; Spinu et al, 2022 ) and in primary compared to managed forests (Asbeck, Kozák, et al, 2021 ). To our knowledge, this is the first structural complexity enhancement (SCE) experiment done in secondary spruce forests that also addressed the dynamics of TreMs.…”

Section: Introductionmentioning

confidence: 99%

Enhancing structural complexity: An experiment conducted in the Black Forest National Park, Germany

Asbeck

Benneter

Huber

et al. 2023

Ecology and Evolution

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We report on a structural complexity enhancement (SCE) experiment that was designed to test ecological restoration measures in the Black Forest National Park, Germany. The main goal was to understand as to whether the creation of standing and downed deadwood within previously managed, single‐layered Norway spruce ( Picea abies L.) forests accelerates the development of forest structure, richness, and diversity of a range of taxonomic groups. Here we introduce the experimental design and describe the development of stand structure including abundance and richness of tree‐related microhabitats (TreMs) within 5 years after initiation of the experiment in October 2016. To enhance structural complexity in treatment plots, 10 trees per plot were toppled using a skidder winch, and another 10 trees were ring barked at a height of around 60 cm above ground level with a chainsaw. To monitor stand structure, we collected data on common forest attributes such as diameter at breast height (DBH), tree height, and TreMs of all trees in the six experimental and six control plots measuring 0.25 ha in size before the treatments were carried out in 2016 and again in 2020/21. We analyzed the abundance and richness of TreMs using generalized linear mixed models with DBH and treatment vs. control as predictors. The SCE treatment resulted in a significant increase in deadwood volumes (4.2 vs. 439.5 m 3 ) as well as in TreM abundance and richness (increase of 0.74 TreMs per tree). This indicates that the SCE treatment was effective to increase biodiversity‐relevant structures such as deadwood and TreMs, in previously managed Norway spruce‐dominated stands. The ongoing monitoring of a range of taxonomic groups (birds, bats, small mammals, coleoptera, fungi, mosses, and vascular plants) in this experiment will demonstrate to what extent the enhancement in structural complexity will lead to an enrichment in species richness and diversity.

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Pioneer tree species accelerate restoration of tree‐related microhabitats in 50‐year‐old reserves of Białowieża Forest, Poland

Spînu,

Mysiak,

Bauhus

et al. 2023

Ecology and Evolution

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Retention of structural elements such as deadwood and habitat trees at the level of forest stands has been promoted to integrate biodiversity conservation into multipleuse forest management. The conservation value of habitat trees is largely determined by the presence, richness, and abundance of tree-related microhabitats (TreMs). Since TreMs are often lacking in intensively managed forests, an important question of forest conservation is how the abundance and richness of TreMs may be effectively restored. Here, we investigated whether the strict protection of forest through cessation of timber harvesting influenced TreM occurrence at tree and stand levels. For that purpose, we compared four managed and four set-aside stands (0.25 ha each) in the Białowieża Forest, with identical origin following clear-cuts approximately 100 years ago. We found that the abundance and richness of TreMs on living trees were not significantly different between stands that were either conventionally managed or where active forest management ceased 52 years ago. Yet, our analysis of TreMs on tree species with contrasting life-history traits revealed that short-lived, fast-growing species (pioneers) developed TreMs quicker than longer-lived, slower-growing species. Hence, tree species such as Populus or Betula, which supply abundant and diverse TreMs, can play an important role in accelerating habitat restoration.

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Combined retention of large living and dead trees can improve provision of tree-related microhabitats in Central European montane forests

Cited by 9 publications

References 79 publications

Spatial distribution of Tree-related Microhabitats in a primeval mountain forest: from natural patterns to landscape planning and forest management recommendations

Spatial distribution of Tree-related Microhabitats in a primeval mountain forest: from natural patterns to landscape planning and forest management recommendations

Enhancing structural complexity: An experiment conducted in the Black Forest National Park, Germany

Pioneer tree species accelerate restoration of tree‐related microhabitats in 50‐year‐old reserves of Białowieża Forest, Poland

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