Abstract
Boreal forests are highly susceptible to wildfire, and post-fire changes in soil temperature and moisture have the potential to transform large areas of the landscape from a net sink to a net source of carbon (C). Understanding the ecological controls that regulate these disturbance effects is critical to developing models of ecosystem response to changes in fire frequency and severity. This paper combines laboratory and field measurements along a chronosequence of burned black spruce stands into regression analyses and models that assess relationships between moss succession, soil microclimate, decomposition, and C source-sink dynamics. Results indicate that post-fire changes in temperature and substrate quality increased decomposition in humic materials by a factor of 3.0 to 4.0 in the first 7 years after fire. Bryophyte species exhibited a distinct successional pattern in the first five decades after fire that corresponded to decreased soil temperature and increased C accumulation in organic soils. Potential rates of C exchange in mosses were greatest in early successional species and declined as the stand matured. Residual sources of CO2 (those not attributed to moss respiration or humic decomposition) increased as a function of stand age, reflecting increased contributions from roots as the stand recovered from disturbance. Together, the field measurements, laboratory experiments, and models provide strong evidence that interactions between moss and plant succession, soil temperature, and soil moisture largely regulate C source-sink dynamics from black spruce systems in the first century following fire disturbance.
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Abbreviations
- ΔR :
-
non-microclimate driven changes in respiration
- B:
-
burned material
- BD:
-
bulk density
- C:
-
carbon
- CO :
-
control material
- FD:
-
fibric decomposition
- F(T):
-
flux associated with a given incubation temperature
- FT:
-
field CO2 flux
- HD:
-
humic decomposition
- MR:
-
moss respiration
- RF:
-
temperature functions for respiration
- RR:
-
residual sources of respiration
- T :
-
temperature
- T h :
-
thickness of soil layer
- WHC:
-
water holding capacity
References
A.N.D. Auclair T.B. Carter (1993) ArticleTitleForest wildfires as a recent source of CO2 at northern latitudes Can. J. For. Res. 23 1530–1536
R.A. Black L.C. Bliss (1980) ArticleTitleReproductive ecology of Picea mariana at treeline near Inuvik, Northwest Territories, Canada Ecol. Monogr. 50 IssueID3 331–354 Occurrence Handle10.2307/2937255
E. Bååth K. Arnebrant (1994) ArticleTitleGrowth rate and response of bacterial communities to pH in limed and ash treated forest soils Soil Biol. Biochem. 26 995–1001 Occurrence Handle10.1016/0038-0717(94)90114-7
B. Bond-Lamberty C. Wang S.T. Gower (2004) ArticleTitleNet primary production and net ecosystem production of a boreal black spruce wildfire chronosequence Glob. Change Biol. 10 473–487 Occurrence Handle10.1111/j.1529-8817.2003.0742.x
R.A. Burke R.G. Zepp M.A. Tarr W.M. Miller B.J. Stocks (1997) ArticleTitleEffect of fire on soil-atmosphere exchange of methane and carbon dioxide in Canadian boreal forest sites J. Geophys. Res. 102 IssueIDD24 29289–29300 Occurrence Handle10.1029/97JD01331
T.R. Christensen S. Jonasson A. Michelsen T.V. Calaghan M. Hastrom (1998) ArticleTitleEnvironmental control on soil respiration in the Eurasian and Greenlandic Arctic J. Geophys. Res. 103 29015–29021 Occurrence Handle10.1029/98JD00084
R.S. Clymo P.M. Hayward (1982) The ecology of Sphagnum A.J.E. Smith (Eds) Bryophyte Ecology Chapman and Hall London 229–289
R.K. Dixon S. Brown R.A. Houghton A.M. Solomon M.C. Trexler J. Wisniewski (1994) Ecological Studies 63. Long-term Forest Dynamics of the Temperate Zone: A Case Study of Late-quaternary Forests in Eastern North America Springer-Verlag New York 439
P.W. Flanagan A.K. Veum (1974) Relationships between respiration, weight loss, temperature and moisture in organic residues on tundra A.J. Holding O.W. Heal S.F. MacLean SuffixJr. P.W. Flanagan (Eds) Soil Organisms and Decomposition in Tundra Tundra Biome Steering Committee Stockholm 249–277
M.D. Flannigan K.A. Logan B.D. Amiro W.R. Skinner B.J. Stocks (2005) ArticleTitleFuture area burned in Canada Climatic Change 72 1–16 Occurrence Handle10.1007/s10584-005-5935-y
D.R. Foster (1985) ArticleTitleVegetation development following fire in Picea mariana (black spruce)-Pleurozium forests of southeastern Labrador, Canada J. Ecol. 73 517–534 Occurrence Handle10.2307/2260491
H. Fritze T. Pennanen J. Pietkäinen (1993) ArticleTitleRecovery of soil microbial biomass and activity from prescribed burning Can. J. For. Res. 23 1286–1290
Gillett N.P., Weaver A.J., Zwiers F.W. and Flannigan M.D. 2004. Detecting the effect of climate change on Canadian forest fires. Geophys. Res. Lett. 31: L18211 1– 4. doi: 10.1029/2004Gh020876.
E. Gorham (1991) ArticleTitleNorthern peatlands: role in the carbon cycle and probable responses to climate warming Ecol. Appl. 1 182–195
M.L. Goulden S.C. Wofsy J.W. Harden S.E. Trumbore P.M. Crill S.T. Gower T. Fries B.C. Daube S.M. Fan D.J. Sutton A. Bazzaz J.W. Munger (1998) ArticleTitleSensitivity of boreal forest carbon to soil thaw Science 279 214–217 Occurrence Handle10.1126/science.279.5348.214
J. Gulledge J. Schimel (2000) ArticleTitleControls on CO2 and CH4 fluxes across a mosaic of forest ecosystems in interior Alaska Ecosystems 3 269–282 Occurrence Handle10.1007/s100210000025
J.W. Harden K.P. O’Neill S.E. Trumbore H. Veldhuis B.J. Stocks (1997) ArticleTitleMoss and soil contributions to the annual net carbon flux of a maturing boreal forest J. Geophys. Res. 102 IssueIDD24 28805–28816 Occurrence Handle10.1029/97JD02237
J.W. Harden S.E. Trumbore B.J. Stocks A. Hirsch S.T. Gower K.P. O’Neill E.S. Kasischke (2000) ArticleTitleThe role of fire in the boreal carbon budget Glob. Change Biol. 6 IssueIDs1 174–184 Occurrence Handle10.1046/j.1365-2486.2000.06019.x
J.A. Hicke G.P. Asner E.S. Kasischke N.H.F. French J.T. Randerson B.J. Stocks C.J. Tucker S.O. Los C.B. Field (2003) ArticleTitlePost fire response of North American net primary productivity measured by satellite imagery Glob. Change Biol. 9 1145–1157 Occurrence Handle10.1046/j.1365-2486.2003.00658.x
J.F. Johnstone E.S. Kasischke (2005) ArticleTitleStand-level effects of burn severity on post-fire regeneration in a recently burned black spruce forest Can J. For. Res. 35 2151–2163 Occurrence Handle10.1139/x05-087
E.S. Kasischke K.P. O’Neill N.H.F. French L.L. Borgeau-Chavez (2000) Controls on patterns of biomass burning in Alaskan boreal forests E.S. Kasischke B.J. Stocks (Eds) FireClimate Changeand Carbon Cycling in the North American Boreal Forest Springer-Verlag New York 173–196
M. Litvak S. Miller S.C. Wofsy M. Goulden (2003) ArticleTitleEffect of stand age on whole ecosystem CO2 exchange in the Canadian boreal forest J. Geophys. Res. 108 IssueID3 WFX6-1–WFX6-11 Occurrence Handle10.1029/2001JD000854
R.E. Longton (1988) Biology of Polar Bryophytes and Lichens Cambridge University Press Cambridge
D.A. MacLean S.J. Woodley M.G. Weber R.W. Wein (1983) Fire and nutrient cycling R.W. Wein D.A. MacLean (Eds) The Role of Fire in the Northern Circumpolar Ecosystem John Wiley and Sons Chichester, England 11–132
E. Maikawa K.A. Kershaw (1976) ArticleTitleStudies on lichen-dominated systems. XIX. The post fire recovery sequence of black-spruce lichen woodland in the Abitau Lake Region Can. J. Bot. 54 2679–2687 Occurrence Handle10.1139/b76-288
D.H. Mann C.L. Fastie E.L. Rowland N.H. Bigelow (1995) ArticleTitleSpruce succession, disturbanceand geomorphology on the Tanana River floodplain, Alaska Ecoscience 2 184–195
O’Neill K.P. 2000. Changes in carbon dynamics following wildfire in soils of interior Alaska. Ph.D. Thesis. Duke University, Durham, NC.
K.P. O’Neill E.S. Kasischke D.D. Richter (2002) ArticleTitleEnvironmental controls on soil CO2 efflux following fire in black sprucewhite spruceand aspen stands of interior Alaska Can. J. For. Res. 32 IssueID9 1525–1541 Occurrence Handle10.1139/x02-077
K.P. O’Neill E.S. Kasischke D.D. Richter (2003) ArticleTitleSeasonal and decadal patterns of soil carbon uptake and emission along an age-sequence of burned black spruce stands in interior Alaska J. Geophys. Res. Atmos. 108 IssueIDD1 8155 Occurrence Handle10.1029/2001JD000443
J. Pietikäinen H. Fritze (1996) Soil microbial biomass: determination and reaction to burning and ash fertilization J.G. Goldammer V.V. Furyaev (Eds) Fire in Ecosystems of Boreal Eurasia Kluwer Academic Publishers The Netherlands 337–349
J. Pietikäinen R. Hiukka H. Fritze (2000) ArticleTitleDoes short-term heating of forest humus change its properties as a substrate for microbes? Soil Biol. Biochem. 32 277–288 Occurrence Handle10.1016/S0038-0717(99)00164-9
G. Rapalee S.E. Trumbore E.A. Davidson J.W. Harden H. Veldhuis (1998) ArticleTitleEstimating soil carbon stocks and fluxes in a boreal forest landscape Global Biogeochem. Cyc. 12 687–701 Occurrence Handle10.1029/98GB02336
D.D. Richter K.P. O’Neill E.S. Kasischke (2000) Stimulation of soil respiration in burned black spruce (Picea mariana L.) forest ecosystems: a hypothesis E.S. Kasischke B.J. Stocks (Eds) FireClimate Changeand Carbon Cycling in the North American Boreal Forest Springer-Verlag New York 164–178
R.E. Schlentner K. Cleve ParticleVan (1985) ArticleTitleRelationships between CO2 evolution from soil, substrate temperatureand substrate moisture in four mature forest types in interior Alaska Can. J. For. Res. 15 97–106
O. Skre W.C. Oechel (1981) ArticleTitleMoss functioning in different taiga ecosystems in interior Alaska. I. Seasonal, phenotypic, and drought effects of photosynthesis and response patterns Oecologia 48 50–59 Occurrence Handle10.1007/BF00346987
B.J. Stocks M.A. Fosberg M.B. Wotton T.J. Lynham K.C. Ryan (2000) Climate change and forest fire activity in North American boreal forests E.S. Kasischke B.J. Stocks (Eds) FireClimate Changeand Carbon Cycling in the North American Boreal Forest Springer-Verlag New York 312–319
B.J. Stocks M.A. Fosberg T.J. Lynham L. Mearns B.M. Wotton Q. Yang J.-Z. Jin K. Lawrence G.R. Hartley J.A. Mason D.W. McKenney (1998) ArticleTitleClimate change and forest fire potential in Russian and Canadian boreal forests Climatic Change 38 1–13 Occurrence Handle10.1023/A:1005306001055
K. Cleve ParticleVan D. Sprague (1971) ArticleTitleRespiration rates in the forest floor of birch and aspen stands in interior Alaska Arc. Alp. Res. 3 IssueID1 17–26 Occurrence Handle10.2307/1550380
K. Cleve ParticleVan J. Yarie (1986) Interaction of temperaturemoistureand soil chemistry in controlling nutrient cycling and ecosystem development in the Alaskan taiga K. Cleve ParticleVan F.S. Chapin SuffixIII P. Flanagan L.A. Viereck C.T. Dyrness (Eds) Forest Ecosystems in the Alaskan Taiga Springer-Verlag New York 160–189
K. Cleve ParticleVan L.K. Oliver P. Schlentner L.A. Viereck C.T. Dyrness (1983) ArticleTitleProductivity and nutrient cycling in taiga forest ecosystems Can. J. For. Res. 13 703–720
L.A. Viereck (1975) ArticleTitleForest ecology of the Alaskan taiga Quat. Res. 3 465–495 Occurrence Handle10.1016/0033-5894(73)90009-4
J. Yarie S. Billings (2002) ArticleTitleCarbon balance of the taiga forest within Alaska: present and future Can. J. For. Res. 32 IssueID5 757–767 Occurrence Handle10.1139/x01-075
Q. Zhuang A.D. McGuire K.P. O’Neill J.W. Harden V.E. Romanovsky J. Yarie (2003) ArticleTitleModeling soil thermal and carbon dynamics of a fire chronosequence in interior Alaska J. Geophys Res. Atmos. 108 IssueID1 FFR 3-1–FFR 3-26
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O’Neill, K.P., Richter, D.D. & Kasischke, E.S. Succession-driven changes in soil respiration following fire in black spruce stands of interior Alaska. Biogeochemistry 80, 1–20 (2006). https://doi.org/10.1007/s10533-005-5964-7
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DOI: https://doi.org/10.1007/s10533-005-5964-7