Data from: Multi-scale heterogeneity in vegetation and soil carbon in exurban residential land of southeastern Michigan, USA
Exurban residential land (one housing unit per 0.2–16.2 ha) is growing in importance as a human-dominated land use. Carbon storage in the soils and vegetation of exurban land is poorly known, as are the effects on C storage of choices made by developers and residents. We studied C storage in exurban...
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Zusammenfassung: | Exurban residential land (one housing unit per 0.2–16.2 ha) is growing in
importance as a human-dominated land use. Carbon storage in the soils and
vegetation of exurban land is poorly known, as are the effects on C
storage of choices made by developers and residents. We studied C storage
in exurban yards in southeastern Michigan, USA, across a range of parcel
sizes and different types of neighborhoods. We divided each residential
parcel into ecological zones (EZ) characterized by vegetation, soil, and
human behavior such as mowing, irrigation, and raking. We found a
heterogeneous mixture of trees and shrubs, turfgrasses, mulched gardens,
old-field vegetation, and impervious surfaces. The most extensive zone
type was turfgrass with sparse woody vegetation (mean 26% of parcel area),
followed by dense woody vegetation (mean 21% of parcel area). Areas of
turfgrass with sparse woody vegetation had trees in larger size classes
(> 50 cm dbh) than did areas of dense woody vegetation. Using
aerial photointerpretation, we scaled up C storage to neighborhoods.
Varying C storage by neighborhood type resulted from differences in
impervious area (8–26% of parcel area) and area of dense woody vegetation
(11–28%). Averaged and multiplied across areas in differing neighborhood
types, exurban residential land contained 5240 ± 865 g C/m2 in vegetation,
highly sensitive to large trees, and 13 800 ± 1290 g C/m2 in soils (based
on a combined sampling and modeling approach). These contents are greater
than for agricultural land in the region, but lower than for mature forest
stands. Compared with mature forests, exurban land contained more shrubs
and less downed woody debris and it had similar tree size-class
distributions up to 40 cm dbh but far fewer trees in larger size classes.
If the trees continue to grow, exurban residential land could sequester
additional C for decades. Patterns and processes of C storage in exurban
residential land were driven by land management practices that affect soil
and vegetation, reflecting the choices of designers, developers, and
residents. This study provides an example of human-mediated C storage in a
coupled human–natural system. |
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DOI: | 10.5061/dryad.7g6v3 |