Soil organic matter dynamics along gradients in temperature and land use on the Island of Hawaii

We studied soil organic matter (SOM) dynamics in allophanic soils (Udands) along independent gradients of temperature (altitude) and land use (forest-pasture) on the island of Hawaii. Using an integrated '3C signal derived from land conversion along with measurements of soil respiration and soil carbon, we separated rapid, intermediate, and very slow turnover SOM pools, and estimated turnover times for the large intermediate pool. These estimates were compared to independent estimates using either bomb-derived soil 14C or the Century soil organic matter model. All calculations based on a three-pool SOM structure yield rates of turnover that are 3 times slower than those produced by a single pool model. Accordingly, analyses of potential feedbacks between changes in climate, atmospheric C02, and soil carbon should incorporate the heterogeneous nature of soil organic matter. We estimate that roughly three-quarters of the carbon in the top 20 cm of these soils has turnover times less than 30 yr. Turnover times for intermediate SOM double with a 10'C change in mean annual temperature, suggesting that recalcitrant pools of SOM may be as sensitive to changes in temperature as the smaller labile pools.

[1]  Robert J. Scholes,et al.  Observations and modeling of biomass and soil organic matter dynamics for the grassland biome worldwide , 1993 .

[2]  M. R. Carter,et al.  Soil Sampling and Methods of Analysis , 1993 .

[3]  S. Trumbore Comparison of carbon dynamics in tropical and temperate soils using radiocarbon measurements , 1993 .

[4]  Peter M. Vitousek,et al.  Tropical soils could dominate the short-term carbon cycle feedbacks to increased global temperatures , 1992 .

[5]  D. Jenkinson,et al.  Model estimates of CO2 emissions from soil in response to global warming , 1991, Nature.

[6]  W. Parton,et al.  Grassland biogeochemistry: Links to atmospheric processes , 1990 .

[7]  I. Fung,et al.  The sensitivity of terrestrial carbon storage to climate change , 1990, Nature.

[8]  C. Cerri,et al.  Organic matter and natural carbon-13 distribution in forested and cultivated oxisols , 1989 .

[9]  W. Parton,et al.  Dynamics of C, N, P and S in grassland soils: a model , 1988 .

[10]  H. Mooney,et al.  Exchange of Materials Between Terrestrial Ecosystems and the Atmosphere , 1987, Science.

[11]  W. Parton,et al.  Analysis of factors controlling soil organic matter levels in Great Plains grasslands , 1987 .

[12]  K. Cleve,et al.  Seasonal patterns of soil respiration and CO2 evolution following harvesting in the white spruce forests of interior Alaska , 1987 .

[13]  D. Schimel Carbon and nitrogen turnover in adjacent grassland and cropland ecosystems , 1986 .

[14]  W. Post,et al.  Influence of climate, soil moisture, and succession on forest carbon and nitrogen cycles , 1986 .

[15]  K. Cleve,et al.  Relationships between CO2 evolution from soil, substrate temperature, and substrate moisture in four mature forest types in interior Alaska , 1985 .

[16]  W. R. Emanuel,et al.  Modeling terrestrial ecosystems in the global carbon cycle with shifts in carbon storage capacity by land-use change , 1984 .

[17]  P. Sollins,et al.  Processes of Soil Organic‐Matter Accretion at a Mudfloe Chronosequence, Mt. Shasta, California , 1983 .

[18]  Sandra Brown,et al.  The Storage and Production of Organic Matter in Tropical Forests and Their Role in the Global Carbon Cycle , 1982 .

[19]  P. Ketner,et al.  Terrestrial primary production and phytomass , 1979 .

[20]  D. S. Jenkinson,et al.  THE TURNOVER OF SOIL ORGANIC MATTER IN SOME OF THE ROTHAMSTED CLASSICAL EXPERIMENTS , 1977 .

[21]  W. Reiners Carbon Dioxide Evolution from the Floor of Three Minnesota Forests , 1968 .

[22]  E. T. Elliott,et al.  Carbon and Nitrogen Dynamics of Soil Organic Matter Fractions from Cultivated Grassland Soils , 1994 .

[23]  I. Fung Models of Oceanic and Terrestrial Sinks of Anthropogenic CO 2 : A Review of the Contemporary Carbon Cycle , 1993 .

[24]  J. Stewart,et al.  Estimates of CO2 production from eroding peat surfaces , 1990 .

[25]  P. Lavelle,et al.  Estimate of organic matter turnover rate in a savanna soil by 13C natural abundance measurements. , 1990 .

[26]  J. Southon,et al.  14C Background Levels in An Accelerator Mass Spectrometry System , 1987, Radiocarbon.

[27]  André Mariotti,et al.  Natural 13C abundance as a tracer for studies of soil organic matter dynamics , 1987 .

[28]  C. Feller,et al.  Application du traçage isotopique naturel en 13C, à l'étude de la dynamique de la matière organique dans les sols , 1985 .

[29]  B. Berg Decomposition of root litter and some factors regulating the process: long-term root litter decomposition in a scots pine forest , 1984 .

[30]  James P. Martin,et al.  Decomposition of 14C-labeled glucose, plant and microbial products and phenols in volcanic ash-derived soils of chile , 1982 .

[31]  B. J. O'brien,et al.  Movement and turnover of soil organic matter as indicated by carbon isotope measurements , 1978 .

[32]  W. Schlesinger CARBON BALANCE IN *:41 17 TERRESTRIAL DETRITUS , 1977 .

[33]  M. Stuiver,et al.  Discussion Reporting of 14C Data , 1977, Radiocarbon.

[34]  David S. Powlson,et al.  The effects of biocidal treatments on metabolism in soil—V: A method for measuring soil biomass , 1976 .

[35]  M. Kononova Humus of Virgin and Cultivated Soils , 1975 .

[36]  R. Warwick Armstrong,et al.  Atlas of Hawaii , 1973 .

[37]  W. Parton,et al.  University of New Hampshire Scholars' Repository University of New Hampshire Scholars' Repository , 2022 .