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Link to original content: https://pubmed.ncbi.nlm.nih.gov/38429441
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Review
. 2024 Mar 2;19(1):9.
doi: 10.1186/s13021-024-00255-3.

Black carbon in urban soils: land use and climate drive variation at the surface

Molly Burke  1   2 Erika Marín-Spiotta  3 Alexandra G Ponette-González  4   5   6
Affiliations
Review

Black carbon in urban soils: land use and climate drive variation at the surface

Molly Burke et al. Carbon Balance Manag. .

Abstract

Background: Black carbon (BC) encompasses a range of carbonaceous materials--including soot, char, and charcoal--derived from the incomplete combustion of fossil fuels and biomass. Urban soils can become enriched in BC due to proximity to these combustion sources. We conducted a literature review of BC in urban soils globally and found 26 studies reporting BC and total organic carbon (TOC) content collected to a maximum of 578 cm depth in urban soils across 35 cities and 10 countries. We recorded data on city, climate, and land use/land cover characteristics to examine drivers of BC content and contribution to TOC in soil.

Results: All studies were conducted in the northern hemisphere, with 68% of the data points collected in China and the United States. Surface samples (0-20 cm) accounted for 62% of samples in the dataset. Therefore, we focused our analysis on 0-10 cm and 10-20 cm depths. Urban soil BC content ranged from 0-124 mg/g (median = 3 mg/g) at 0-10 cm and from 0-53 mg/g (median = 2.8 mg/g) at 10-20 cm depth. The median proportional contribution of BC to TOC was 23% and 15% at 0-10 cm and 10-20 cm, respectively. Surface soils sampled in industrial land use and near roads had the highest BC contents and proportions, whereas samples from residential sites had among the lowest. Soil BC content decreased with mean annual soil temperature.

Conclusions: Our review indicates that BC comprises a major fraction (nearly one quarter) of the TOC in urban surface soils, yet sampling bias towards the surface could hide the potential for BC storage at depth. Land use emerged as an importer driver of soil BC contents and proportions, whereas land cover effects remain uncertain. Warmer and wetter soils were found to have lower soil BC than cooler and drier soils, differences that likely reflect soil BC loss mechanisms. Additional research on urban soil BC at depth and from diverse climates is critical to better understand the role of cities in the global carbon cycle.

Keywords: Air pollution; Cities; Land cover; Nature-based solutions; Organic carbon; Pyrogenic carbon; Roads.

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Conflict of interest statement

The authors declare no competing interests.

Figures

Fig. 1
Fig. 1
Distribution of soil black carbon (BC) samples included in this literature review grouped by sampling depth range. Each point represents one soil sample from the dataset. Soil depth is indicated by the color gradient (dark = closer to the surface, light = deeper in the soil). Spread between samples is meant to improve visualization. There is no x-axis
Fig. 2
Fig. 2
Histograms of soil black carbon (BC), total organic carbon (TOC) content (bins are 5 mg/g), and the contribution of BC to TOC (bins are 5 percent) across all sample depths, 0–10 cm depth (inset), and 10–20 cm depth (inset). Summary statistics include minimum, maximum, mean, and median. Note difference in y-axis scales
Fig. 3
Fig. 3
Black carbon (BC) content (mg/g) and the contribution of BC to TOC in urban soils as a function of land use at 0–10 cm and 10–20 cm depth. Dots indicate mean values. Missing bars are due to lack of land use data
Fig. 4
Fig. 4
Mean black carbon (BC) contents (mg/g) and the contribution of BC to TOC in urban soils as a function of land use and land cover at 0–10 cm and 10–20 cm depth. Missing bars are due to lack of land use data
Fig. 5
Fig. 5
Non-parametric correlations between soil black carbon (BC) and mean annual soil temperature (left) and mean annual precipitation (right) in urban soils at 0–10 cm and 10–20 cm depths. *p < 0.05, **p < 0.01, ***p < 0.001
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