Stand-Level Forest Structure and Avian Habitat: Scale Dependencies in Predicting Occurrence in a Heterogeneous Forest

Abstract We explored the role of stand-level forest structure and spatial extent of forest sampling in models of avian occurrence in northern hardwood-conifer forests for two species: black-throated blue warbler (Dendroica caerulescens) and ovenbird (Seiurus aurocapillus). We estimated site occupancy from point counts at 20 sites and characterized the forest structure at these sites at three spatial extents (0.2, 3.0, and 12.0 ha). Weight of evidence was greatest for habitat models using forest stand structure at the 12.0-ha extent and diminished only slightly at the 3.0-ha extent, a scale that was slightly larger than the average territory size of both species. Habitat models characterized at the 0.2-ha extent had low support, yet are the closest in design to those used in many of the habitat studies we reviewed. These results suggest that the role of stand-level vegetation may have been underestimated in the past, which will be of interest to land managers who use habitat models to assess the suitability of habitat for species of concern.

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The role of forest stand structure as biodiversity indicator

Forest Ecology and Management ◽

10.1016/j.foreco.2014.07.007 ◽

2014 ◽

Vol 330 ◽

pp. 82-93 ◽

Cited By ~ 48

Author(s):

Tian Gao ◽

Marcus Hedblom ◽

Tobias Emilsson ◽

Anders Busse Nielsen

Keyword(s):

Stand Structure ◽

Forest Stand ◽

Biodiversity Indicator ◽

Forest Stand Structure

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Fuels planning: science synthesis and integration; forest structure and fire hazard fact sheet 04: role of silviculture in fuel treatments

10.2737/rmrs-rn-22-v4 ◽

2004 ◽

Author(s):

Rocky Mountain Research Station USDA Forest Service

Keyword(s):

Forest Structure ◽

Fire Hazard ◽

Fuel Treatments ◽

Fact Sheet

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Assessing Wood and Soil Carbon Losses from a Forest-Peat Fire in the Boreo-Nemoral Zone

Forests ◽

10.3390/f12070880 ◽

2021 ◽

Vol 12 (7) ◽

pp. 880

Author(s):

Andrey Sirin ◽

Alexander Maslov ◽

Dmitry Makarov ◽

Yakov Gulbe ◽

Hans Joosten

Keyword(s):

Soil Carbon ◽

Stand Structure ◽

Peat Soil ◽

Burned Area ◽

Tree Biomass ◽

Carbon Loss ◽

Forest Stand Structure ◽

Peat Fire ◽

Peat Fires ◽

Carbon Losses

Forest-peat fires are notable for their difficulty in estimating carbon losses. Combined carbon losses from tree biomass and peat soil were estimated at an 8 ha forest-peat fire in the Moscow region after catastrophic fires in 2010. The loss of tree biomass carbon was assessed by reconstructing forest stand structure using the classification of pre-fire high-resolution satellite imagery and after-fire ground survey of the same forest classes in adjacent areas. Soil carbon loss was assessed by using the root collars of stumps to reconstruct the pre-fire soil surface and interpolating the peat characteristics of adjacent non-burned areas. The mean (median) depth of peat losses across the burned area was 15 ± 8 (14) cm, varying from 13 ± 5 (11) to 20 ± 9 (19). Loss of soil carbon was 9.22 ± 3.75–11.0 ± 4.96 (mean) and 8.0–11.0 kg m−2 (median); values exceeding 100 tC ha−1 have also been found in other studies. The estimated soil carbon loss for the entire burned area, 98 (mean) and 92 (median) tC ha−1, significantly exceeds the carbon loss from live (tree) biomass, which averaged 58.8 tC ha−1. The loss of carbon in the forest-peat fire thus equals the release of nearly 400 (soil) and, including the biomass, almost 650 tCO2 ha−1 into the atmosphere, which illustrates the underestimated impact of boreal forest-peat fires on atmospheric gas concentrations and climate.

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