Abstract
Causes and implications of spatial variability in postfire tree density and understory plant cover for patterns of aboveground net primary production (ANPP) and leaf area index (LAI) were examined in ninety 11-year-old lodgepole pine (Pinus contorta var. latifolia Engelm.) stands across the landscape of Yellowstone National Park (YNP), Wyoming, USA. Field studies and aerial photography were used to address three questions: (1) What is the range and spatial pattern of lodgepole pine sapling density across the burned Yellowstone landscape and what factors best explain this variability? (2) How do ANPP and LAI vary across the landscape and is their variation explained by abiotic factors, sapling density, or both? (3) What is the predicted spatial pattern of ANPP and LAI across the burned Yellowstone landscape? Stand density spanned six orders of magnitude, ranging from zero to 535,000 saplings ha−1, and it decreased with increasing elevation and with increasing distance from unburned forest (r 2 = 0.37). Postfire densities mapped from 1:30,000 aerial photography revealed that 66% of the burned area had densities less than 5000 saplings ha−1 and approximately 25% had densities greater than 10,000 saplings ha−1; stand density varied spatially in a fine-grained mosaic. New allometric equations were developed to predict aboveground biomass, ANPP, and LAI of lodgepole pine saplings and the 25 most common herbaceous and shrub species in the burned forests. These allometrics were then used with field data on sapling size, sapling density, and percent cover of graminoid, forb, and shrub species to compute stand-level ANPP and LAI. Total ANPP averaged 2.8 Mg ha−1y−1 but ranged from 0.04 to 15.12 Mg ha−1y−1. Total LAI averaged 0.80 m2 m−2 and ranged from 0.01 to 6.87 m2 m−2. Variation in ANPP and LAI was explained by both sapling density and abiotic factors (elevation and soil class) (ANOVA, r 2 = 0.80); abiotic variables explained 51%–54% of this variation. The proportion of total ANPP contributed by herbaceous plants and shrubs declined sharply with increasing sapling density (r 2 = 0.72) and increased with elevation (r 2 = 0.36). However, total herbaceous productivity was always less than 2.7 Mg ha−1 y−1, and herbaceous productivity did not compensate for tree production when trees were sparse. When extrapolated to the landscape, 68% of the burned landscape was characterized by ANPP values less than 2.0 Mg ha−1y−1, 22% by values ranging from 2 to 4 Mg ha−1y−1, and the remaining 10% by values greater than 4 Mg ha−1y−1. The spatial patterns of ANPP and LAI were less heterogeneous than patterns of sapling density but still showed fine-grained variation in rates. For some ecosystem processes, postfire spatial heterogeneity within a successional stage may be similar in magnitude to the temporal variation observed through succession.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
BC Amiro (2001) ArticleTitlePaired-tower measurements of carbon and energy fluxes following disturbance in the boreal forest Global Change Biol 7 253–268 Occurrence Handle10.1046/j.1365-2486.2001.00398.x
JE Anderson WH Romme (1991) ArticleTitleInitial floristics in lodgepole pine (Pinus contorta) forests following the 1988 Yellowstone fires Int J Wildland Fire 1 119–24
AND Auclair TB Carter (1993) ArticleTitleForest wildfires as a recent source of CO2 at northern latitudes Can J Forest Res 23 1528–36 Occurrence Handle1:CAS:528:DyaK2cXjtVers7k%3D
BV Barnes DR Zak SR Denton SH Spurr (1998) Forest ecology John Wiley & Sons New York
WC Bessie EA Johnson (1995) ArticleTitleThe relative importance of fuels and weather on fire behavior in subalpine forests Ecology 76 747–62
D Binkley FW Smith Y Son (1995) ArticleTitleNutrient supply and declines in leaf area and production in lodgepole pine Can J Forest Res 25 621–628
D Binkley U Olsson T Rochelle T Stohlgren N Nikolov (2003) ArticleTitleStructure, production and resource use in some old-growth spruce/fir forests in the Front Range of the Rocky Mountains, USA Forest Ecol Manage 172 271–9 Occurrence Handle10.1016/S0378-1127(01)00794-0
FH Bormann GE Likens (1979) Pattern and process in a forested ecosystem Springer-Verlag New York
EO Box BN Holben V Kalb (1989) ArticleTitleAccuracy of AVHRR vegetation index as a predictor of biomass, primary productivity and net CO2 flux Vegetatio 80 71–89
SL Brown PE Schroeder (1999) ArticleTitleSpatial patterns of aboveground production and mortality of woody biomass for eastern U.S. forests Ecol Applic 9 968–80
PJ Cattelino IR Noble RO Slatyer SR Kessel (1979) ArticleTitlePredicting the multiple pathways of plant succession Environ Manage 3 41–50
W Chen JM Chen DT Price J Cihlar (2002) ArticleTitleEffects of stand age on net primary productivity of boreal black spruce forests in Ontario, Canada Can J Forest Res 32 833–842 Occurrence Handle10.1139/x01-165
JM Chen PM Rich ST Gower JM Norman S Plummer (1997) ArticleTitleLeaf area index of boreal forests: theory, techniques, and measurements J Geophys Res 102 29429–29443 Occurrence Handle10.1029/97JD01107
NE Christensen JK Agee PF Brussard (1989) ArticleTitleInterpreting the Yellowstone fires of 1988 BioScience 39 678–85
DA Clark S Brown DW Kicklighter JQ Chambers JE Thomlinson J Ni (2001) ArticleTitleMeasuring net primary production in forests: concepts and field methods Ecol Applic 11 356–370
PG Comeau JP Kimmins (1989) ArticleTitleAbove- and belowground biomass and production of lodgepole pine on sites with differing soil moisture regimes Can J Forest Res 19 447–54
RC Congalton (1991) ArticleTitleA review of assessing the accuracy of classifications of remotely sensed data Remote Sensing Environ 37 35–46 Occurrence Handle10.1016/0034-4257(91)90048-B
VH Dale LA Joyce S McNulty RP Neilson MP Ayres MD Flannigan PJ Hanson LC Irland AE Lugo CJ Peterson D Simberloff FJ Swanson BJ Stocks BM Wotton (2001) ArticleTitleClimate change and forest disturbances BioScience 51 723–34
RJ Day (1972) ArticleTitleStand structure, succession, and use of southern Alberta’s Rocky Mountain forest Ecology 53 472–8
DG Despain (1983) ArticleTitleNonpyrogenous climax lodgepole pine communities in Yellowstone National Park Ecology 64 231–4
DG Despain (1990) Yellowstone vegetation: consequences of environment and history in a natural setting Rinehart Publishers Boulder, CO 239
Dirks RA, Martner BE. 1982. The climate of Yellowstone and Grand Teton National Parks. Occasional Paper No. 6, U.S. National Park Service, Washington, DC
M Ellis CD von Dohlen JE Anderson WH Romme (1994) Some important factors affecting density of lodgepole pine seedlings following the 1988 Yellowstone fires D Despain (Eds) Plants and their environments: proceedings of the first biennial scientific conference on the Greater Yellowstone Ecosystem. Technical Report NPS/NRYE/NRTR-93/XX. U.S. Department of the Interior, National Park Service Natural Resources Publication Office Denver, CO 139–50
InstitutionalAuthorNameERDAS, Inc. (1999) ERDAS field guide ERDAS Atlanta, GA 394
InstitutionalAuthorNameESRI, Inc. (1992) ARC/INFO user’s guide. Cell-based modeling with GRID Environmental Systems Research Institute Redlands, CA
TJ Fahey DH Knight (1986) ArticleTitleLodgepole pine ecosystems Bioscience 36 610–6
KS Fassnacht ST Gower (1997) ArticleTitleInerrelationships among the edaphic and stand characteristics, leaf area index, and aboveground net primary production of upland forests in north central Wisconsin Can J Forest Res 27 1058–67 Occurrence Handle10.1139/cjfr-27-7-1058
MD Flannigan CE Wagner ParticleVan (1991) ArticleTitleClimate change and wildfire in Canada Can J Forest Res 21 66–72
MD Flannigan Wotton BM (2001) Climate, weather and area burned EA Johnson K Miyanishi (Eds) Forest fires Academic Press New York 351–73
MD Flannigan Y Bergeron O Engelmark BM Wotton (1998) ArticleTitleFuture wildfire in circumboreal forests in relation to global warming J Veg Sci 9 477–82
DR Foster DH Knight JF Franklin (1998) ArticleTitleLandscape patterns and legacies resulting from large, infrequent forest disturbances Ecosystems 1 497–510 Occurrence Handle10.1007/s100219900046
FS Gilliam (1990) The significance of fire in an oligotrophic forest ecosystem Proceedings of the International Symposium on Fire and the Environment: Ecological and Cultural Perspectives. USDA Forest Service General Technical Report SE-69 City Publisher 113–22
ST Gower R McMurtrie D Murty (1996) ArticleTitleAboveground net primary production decline with stand age: potential causes Trends Ecol Evol 11 378–82 Occurrence Handle10.1016/0169-5347(96)10042-2
ST Gower O Krankina RJ Olson M Apps S Linder C Wang (2001) ArticleTitleNet primary production and carbon allocation patterns of boreal forest ecosystems Ecol Applic 11 1395–411
RL Graham MG Turner VH Dale (1990) ArticleTitleHow increasing atmospheric CO2 and climate change affect forests BioScience 40 575–87
AJ Hansen JJ Rotella MPV Kraska D Brown (2000) ArticleTitleSpatial patterns of primary productivity in the Greater Yellowstone Ecosystem Landscape Ecol 15 505–22 Occurrence Handle10.1023/A:1008127228878
SB Jack JN Long (1991) ArticleTitleResponse of leaf area index to density for two contrasting tree species Can J Forest Res 21 1760–4
EA Johnson (1992) Fire and vegetation dynamics Cambridge University Press New York
EA Johnson GI Fryer (1989) ArticleTitlePopulation dynamics in lodgepole pine-Engelmann spruce forests Ecology 70 1335–45
EA Johnson K Miyanishi (.) Forest fires Academic Press New York
EA Johnson DR Wowchuck (1993) ArticleTitleWildfires in the southern Canadian Rocky Mountains and their relationship to mid-tropospheric anomalies Can J Forest Res 23 1213–22
DM Kashian (2002) Landscape variability and convergence in forest structure and function following large fires in Yellowstone National Park. PhD Dissertation University of Wisconsin Madison, WI
Kashian DM, Tinker DB, Turner MG, Scarpace FL, Romme WH. Spatial heterogeneity of lodgepole pine Sapling densities following the fires in Yellow stone National Park, Wyeming, USA. Canadian Journal of Forest Research (In press)
Kashian DM, Turner MG, Romme WH. 2004. Changes in leaf area and stemwood increment with stand development in Yellowstone National Park: Relationships between forest stand structure and function. Ecosystems (In press)
ES Kasischke (2000) Effects of climate change and fire on carbon storage in North American boreal forests ES Kasischke BJ Stocks (Eds) Fire, climate change, and carbon cycling in the boreal forest Springer-Verlag New York 440–52
MG Keane GF Weetman (1987) ArticleTitleLeaf areasapwood cross-sectional area relationships in repressed stands of lodgepole pine Can J Forest Res 17 205–9
RE Keane P Morgan JD White (1999) ArticleTitleTemporal patterns of ecosystem processes on simulated landscapes in Glacier National Park, Montana, USA Landscape Ecol 14 311–29 Occurrence Handle10.1023/A:1008011916649
AK Knapp MD Smith (2001) ArticleTitleVariation among biomes in temporal dynamics of above-ground primary production Science 291 481–4 Occurrence Handle10.1126/science.291.5503.481 Occurrence Handle1:CAS:528:DC%2BD3MXlslensg%3D%3D Occurrence Handle11161201
DH Knight TJ Fahey SW Running AT Harrison LL Wallace (1981) ArticleTitleTranspiration from 100-yr-old lodgepole pine forests estimated with whole-tree potometers Ecology 62 717–26
BE Law PE Thornton J Irvine PM Anthoni S Tuyl Particlevan (2001) ArticleTitleCarbon storage and fluxed in ponderosa pine forests at different developmental stages Global Change Biol 7 755–77 Occurrence Handle10.1046/j.1354-1013.2001.00439.x
GE Likens FH Bormann (1995) Biogeochemistry of a forested ecosystem Springer-Verlag New York
TM Lillesand RW Kiefer (1994) Remote sensing and data interpretation EditionNumber3 John Wiley & Sons New York
CM Litton (2002) Above- and belowground carbon allocation in post-fire lodgepole pine forests: effects of tree density and stand age. PhD Dissertation University of Wyoming Laramie, WY
CM Litton MG Ryan DB Tinker DH Knight (2003) ArticleTitleBelow- and aboveground biomass in young postfire lodgepole pine forests of contrasting tree density Can J Forest Res 33 351–63 Occurrence Handle10.1139/x02-181
CM Litton MG Ryan DH Knight (2004) ArticleTitleEffects of tree density and stand age on carbon allocation patterns in a postfire lodgepole pine Ecol Applic 14 460–475
JN Long FW Smith (1990) ArticleTitleDeterminants of stemwood production in Pinus contorta var. latifolia forests: the influence of site quality and stand structure J Appl Ecol 27 847–56
JN Long FW Smith (1992) ArticleTitleVolume increment in Pinus contorta var. latifolia: the influence of stand development and crown dynamics Forest Ecol Manage 53 53–64 Occurrence Handle10.1016/0378-1127(92)90033-6
JE Lotan DA Perry (1983) Ecology and regeneration of lodgepole pine. Agricultural Handbook 606 Publisher Washington, DC
McGarigal K, Marks BJ. 1995. FRAGSTATS. Spatial analysis program for quantifying landscape structure. USDA Forest Service General Technical Report PNW-GTR-351
M Mencuccini J Grace (1996) ArticleTitleHydraulic conductance, light interception, and needle nutrient concentration in Scots pine stands and their relations with net primary productivity Tree Physiol 16 459–68 Occurrence Handle1:CAS:528:DyaK28Xjt1Wru7w%3D Occurrence Handle14871714
SH Millspaugh C Whitlock PJ Bartlein (2000) ArticleTitleVariations in fire frequency and climate over the past 17000 yr in central Yellowstone National Park Geology 28 211–4 Occurrence Handle10.1130/0091-7613(2000)028<0211:VIFFAC>2.3.CO;2
WH Moir (1969) ArticleTitleThe lodgepole pine zone in Colorado Am Midland Naturalist 81 87–98
WH Moir R Francis (1972) ArticleTitleFoliage biomass and surface area in three Pinus contorta plots in Colorado Forest Sci 18 41– 45
Moore MB. 1981. Geographic variation in lodgepole pine in the central Rocky Mountains. PhD dissertation. Colorado State University, Ft. Collins, CO. 188 p
PS Muir (1993) ArticleTitleDisturbance effects on structure and tree species composition of Pinus contorta forests in western Montana Can J Forest Res 23 1617–25
KL Murphy JM Klopatek CC Klopatek (1998) ArticleTitleThe effects of litter quality and climate on decomposition along an elevational gradient Ecol Applic 8 1061–71
C O’Reilly JN Owens (1989) ArticleTitleShoot, needle, and cambial growth phenology and branch tracheid dimensions in provenances of lodgepole pine Can J Forest Res 22 IssueID2 210–23
AJ Parker KC Parker (1994) ArticleTitleStructural variability of mature lodgepole pine stands on gently sloping terrain in Taylor Park Basin, Colorado Can J Forest Res 24 2020–9
AJ Parker RK Peet (1984) ArticleTitleSize and age structure of conifer forests Ecology 65 1685–9
JA Pearson TJ Fahey DH Knight (1984) ArticleTitleBiomass and leaf area in contrasting lodgepole pine forests Can J Forest Res 14 259–65
JA Pearson DH Knight TJ Fahey (1987) ArticleTitleBiomass and nutrient accumulation during stand development in Wyoming lodgepole pine forests Ecology 68 1966–73
RK Peet (1981) ArticleTitleForest vegetation of the Colorado Front Range Vegetatio 45 3–75 Occurrence Handle10.1007/BF00240202
C Price D Rind (1994) ArticleTitleThe impact of a 2 × CO2 climate on lightning-caused fires J Climatol 7 1484–94 Occurrence Handle10.1175/1520-0442(1994)007<1484:TIOACC>2.0.CO;2
RA Reed ME Finley WH Romme MG Turner (1998) ArticleTitleAboveground net primary production and leaf-area index in early postfire vegetation in Yellowstone National Park Ecosystems 2 88–94 Occurrence Handle10.1007/s100219900061
RA Renkin DG Despain (1992) ArticleTitleFuel moisture, forest type and lightning-caused fire in Yellowstone National Park Can J Forest Res 22 37–45 Occurrence Handle10.1139/x92-005
Rodman A, Shovic HF, Thoma D. 1996. Soils of Yellowstone National Park. Yellowstone Center for Resources, Yellowstone National Park, WY, YCR-NRSR-96-2
WH Romme (1982) ArticleTitleFire and landscape diversity in subalpine forests of Yellowstone National Park Ecol Monogr 52 199–221
WH Romme DG Despain (1989) ArticleTitleHistorical perspective on the Yellowstone fires of 1988 BioScience 39 695–9
WH Romme MG Turner (2004) Ten years after the 1988 Yellowstone fires: is restoration needed? LL Wallace (Eds) After the fires: the ecology of change in Yellowstone National Park Yale University Press New Haven, CT 318–361
M Ryan R Waring (1992) ArticleTitleMaintenance respiration and stand development in a subalpine lodgepole pine forest Ecology 73 2100–8
MG Ryan DJ Binkley J Fownes (1997) ArticleTitleAge-related decline in forest productivity: pattern and process Adv Ecol Res 27 213–62 Occurrence Handle10.1016/S0065-2504(08)60009-4
InstitutionalAuthorNameSAS Institute, Inc (1996) SAS/STAT Software: Changes and Enhancements, through Release 9, Cary SAS Institute Inc NC
Scarpace FL, Weiler PR, Kruepe J. 2000. A simplified method of producing orthophotos. Proceedings of the American Society of Photogrammetry and Remote Sensing, Washington, DC, May 2000
DS Schimel participants VEMAP BH Braswell (1997) ArticleTitleContinental scale variability in ecosystem processes: models, data, and the role of disturbance Ecol Monogr 67 251–71
T Schoennagel (2002) The effects of fire interval and climate on successional patterns in Yellowstone National Park. PhD Dissertation University of Wisconsin Madison, WI
T Schoennagel MG Turner WH Romme (2004) ArticleTitleInfluence of fire interval and serotiny on postfire lodgepole pine (Pinus contorta var. latifolia Engelm.) density in Yellowstone National Park (USA) Ecology . .
DW Smith RO Peterson DB Houston (2003) ArticleTitleYellowstone after wolves BioScience 53 330–40
DG Sprugel (1985) Natural disturbance and ecosystem energetics STA Pickett PS White (Eds) The ecology of natural disturbance and patch dynamics Academic Press New York 335–455
InstitutionalAuthorNameSPSS Inc (1999) Base 10.0 applications guide SPSS Inc Chicago
BJ Stocks (1998) ArticleTitleClimate change and forest fire potential in Russian and Canadian boreal forests Climatic Change 38 1–13
WT Swank DA Crossley SuffixJr (Eds) (1988) Forest hydrology and ecology at Coweeta Springer-Verlag New York
DL Taylor (1980) ArticleTitleBiotic succession of lodgepole pine forests of fire origin in Yellowstone National Park Natl Geogr Res Rep 12 693–702
KP Timoney GP Peterson R Wein (1997) ArticleTitleVegetation development of boreal riparian plant communities after flooding, fire, and logging, Peace River, Canada Forest Ecol Manage 93 101–120
DB Tinker WH Romme WW Hargrove RH Gardner MG Turner (1994) ArticleTitleLandscape-scale heterogeneity in lodgepole pine serotiny Can J Forest Res 24 897–903
MG Turner SR Carpenter (1999) ArticleTitleSpatial variability in ecosystem function Ecosystems 2 383 Occurrence Handle10.1007/s100219900087
MG Turner WH Romme (1994) ArticleTitleLandscape dynamics in crown fire ecosystems Landscape Ecology 9 59–77
MG Turner WW Hargrove RH Gardner WH Romme (1994) ArticleTitleEffects of fire on landscape heterogeneity in Yellowstone National Park, Wyoming J Veg Sci 5 731–42
MG Turner WH Romme RH Gardner WW Hargrove (1997) ArticleTitleEffects of fire size and pattern on early succession in Yellowstone National Park Ecol Monogr 67 411–433
MG Turner WL Baker CJ Peterson RK Peet (1998) ArticleTitleFactors influencing succession: lessons from large, infrequent natural disturbances Ecosystems 1 511–523 Occurrence Handle10.1007/s100219900047
MG Turner WH Romme RH Gardner (1999) ArticleTitlePrefire heterogeneity, fire severity and plant reestablishment in subalpine forests of Yellowstone National Park, Wyoming Int J Wildland Fire 9 21–36 Occurrence Handle10.1071/WF99003
MG Turner RH Gardner RV O’Neill (2001) Pattern and process: Landscape ecology in theory and practice Springer-Verlag New York
TT Veblen (1986) ArticleTitleAge and size structure of subalpine forests in the Colorado Front Range Bull Torrey Bot Club 113 225–240
TT Veblen KS Hadley MS Reid (1991) ArticleTitleDisturbance and stand development of a Colorado sub-alpine forest J Biogeogr 18 707–16
MG Weber MD Flannigan (1997) ArticleTitleCanadian boreal forest ecosystem strucrture and function in a changing climate: Impact on fire regimes Environ Rev 5 145–66 Occurrence Handle10.1139/er-5-3-4-145 Occurrence Handle1:CAS:528:DyaK1cXitVersLs%3D
SA Whipple RL Dix (1979) ArticleTitleAge structure and successional dynamics of a Colorado subalpine forest Am Midland Naturalist 101 142–158
C Wirth E-D Schulze V Kusznetova I Milyukova G Hardes M Siry B Schulze NN Vygodskaya (2002) ArticleTitleComparing the influence of site quality, stand age, fire, and climate on aboveground tree production in Siberian Scots pine forests Tree Physiol 22 537–52 Occurrence Handle1:STN:280:DC%2BD38zgsVehsw%3D%3D Occurrence Handle12045026
BM Wotton MD Flannigan (1993) ArticleTitleLength of the fire season in a changing climate Forestry Chronicles 69 187–192
DR Zak GE Host KS Pregitzer (1989) ArticleTitleRegional variability in nitrogen mineralization, nitrification, and overstory biomass in northern Lower Michigan. 1989 Can J Forest Res 19 1521–6
Acknowledgements
This work could not have been accomplished without the hard work of our 1999 field crew, and we are extremely grateful to them: Heather Arrowwood, Teresa Cohen, Yvonne Corcoran, Jamie Corcoran, Janice Corcoran, Eleanor Erwin, Donna R. Kashian, and Tania Schoennagel. We thank Tania Schoennagel for generously sharing her data on lodgepole pine density so that the goodness of fit of our sapling density map could be evaluated with independent data. Anne Rodman of the GIS Laboratory, Center for Resources, Yellowstone National Park, graciously helped interpret the soils map of YNP for use in our analyses. The University of WyomingNational Park Service Research Center provided valuable logistical support during the field season. Many members of the Yellowstone Ranger Division, particularly Dave Phillips and Kathleen O’Leary of the South Entrance, were extremely helpful during our study. Our ideas benefited from discussions with Mike Ryan and Dennis Knight, and the article was improved by helpful comments from Dennis Knight, Tania Schoennagel, and Erica Smithwick. This research was funded by the Ecology and Ecosystem Studies Programs, National Science Foundation (Grant No. DEB-9806440) and by a grant from the Andrew W. Mellon Foundation.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Turner, M.G., Tinker, D.B., Romme, W.H. et al. Landscape Patterns of Sapling Density, Leaf Area, and Aboveground Net Primary Production in Postfire Lodgepole Pine Forests, Yellowstone National Park (USA). Ecosystems 7, 751–775 (2004). https://doi.org/10.1007/s10021-004-0011-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10021-004-0011-4