Carbon Accumulation and the Possibility of Carbon Losses by Vertical Movement of Dissolved Organic Carbon in Western Siberian Peatlands
Abstract
:1. Introduction
2. Materials and Methods
2.1. Study Site
- Typical ryam (pine–dwarf shrub–peat moss community) is characterised by a low Scots pine layer (Pinus sylvestris f. litwiniwii, height 1.5–4 m), a well-developed dwarf shrub layer (Ledum palustre, Chamaedaphne calyculata), and a moss layer dominated by Sphagnum fuscum with a minor admixture of S. angustifolium and S. divinum;
- Tall ryam, which is found on shallower peat near the outer edges of the peatland, is similar to the typical ryam, except that it has tall pine trees (Pinus sylvestris f. uliginosa, height 6–10 m) and Sphagnum angustifolium dominates the moss layer;
- The ridge–hollow complex features ridges, which are elongated perpendicular to the water flowlines; they are occupied by typical ryam communities, alternating with waterlogged sedge–peat moss hollows (Carex limosa, Scheuchzeria palustris, Eriophorum russeolum, Sphagnum balticum, S. majus, S. jensenii);
- Treeless throughflow fens, as well as Sphagnum lawns with hollow vegetation and occasional scattered hummocks, which are located within limited areas in the lower reaches of the peatland water catchment [41].
2.2. Field Sampling
2.3. Identification of Peat Types
2.4. Bulk Density, Carbon, and Ash Content
2.5. Separation of DOC and POC
2.6. AMS C Analysis
2.7. Calculation of Accumulation Rates
2.8. Calculation of DOC Downward Velocity
3. Results
3.1. Stratigraphy
3.2. Peat Ages and Accumulation Rates
3.3. Bulk Density and Ash Content
3.4. Carbon Accumulation Rate
3.5. POC and DOC
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Core | Habitat Description | WT Depth (cm) | Peat Depth (cm) |
---|---|---|---|
2 | Typical transition from ryam to dry peatland; covered by pine trees up to 3 m tall, dwarf shrubs (Ericaceae), and Sphagnum fuscum. | 20–30 | 530 |
5, 19 | Ridge in ridge–hollow complex; covered by low pine (up to 2 m tall), dwarf shrubs (Ericaceae), and Sphagnum fuscum. | 15–20 | 390, 400 |
5-5 | Ecotone between ridge and hollow; covered by mixed species from both habitats: cottongrass, Sphagnum mosses (S. fuscum, S. balticum), dwarf shrubs (Ericaceae). | 5–10 | 310 |
18 | Floating Sphagnum mat close to the lake; covered by Scheuchzeria, sedges (Carex limosa), and Sphagnum mosses (S. papillosum, S. balticum). | 2–5 | 480 |
27 | Ridge in ridge–pool complex; treeless ridge with dwarf shrubs and Sphagnum mosses. | 10–15 | 400 |
31 | Hollow in ridge–hollow complex; covered by sedges (Carex limosa) and Sphagnum balticum. | 5–10 | 380 |
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Zarov, E.A.; Lapshina, E.D.; Kuhlmann, I.; Schulze, E.-D. Carbon Accumulation and the Possibility of Carbon Losses by Vertical Movement of Dissolved Organic Carbon in Western Siberian Peatlands. Forests 2023, 14, 2393. https://doi.org/10.3390/f14122393
Zarov EA, Lapshina ED, Kuhlmann I, Schulze E-D. Carbon Accumulation and the Possibility of Carbon Losses by Vertical Movement of Dissolved Organic Carbon in Western Siberian Peatlands. Forests. 2023; 14(12):2393. https://doi.org/10.3390/f14122393
Chicago/Turabian StyleZarov, Evgeny A., Elena D. Lapshina, Iris Kuhlmann, and Ernst-Detlef Schulze. 2023. "Carbon Accumulation and the Possibility of Carbon Losses by Vertical Movement of Dissolved Organic Carbon in Western Siberian Peatlands" Forests 14, no. 12: 2393. https://doi.org/10.3390/f14122393
APA StyleZarov, E. A., Lapshina, E. D., Kuhlmann, I., & Schulze, E. -D. (2023). Carbon Accumulation and the Possibility of Carbon Losses by Vertical Movement of Dissolved Organic Carbon in Western Siberian Peatlands. Forests, 14(12), 2393. https://doi.org/10.3390/f14122393