Biomass, Productivity, Leaf Longevity, and Forest Structure in the Central Himalaya

Patterns of leaf characteristics, forest structure, tree species diversity, bio- mass, and productivity across a gradient of 3300 m and 15.70C in mean annual temperature in Kumaun, in the Indian central Himalaya, were summarized and compared to values from other similar forests. Throughout the elevational gradient, the annual rainfall was high (100-300 cm), but not correlated with elevation. Evergreen species with a 1-yr leaf life-span dominated most of the elevational transect; above 1800 m, species with deciduous and multiyear evergreen leaves were also well represented. Although variability among sites within forest types was high, a number of consistent patterns were apparent. Forests of Pinus roxburghii and those at high elevations were most consistently different from other forest types. Leaf life-span was not strongly correlated with leaf mass, specific leaf mass, or leaf production efficiency (net primary productivity per unit leaf mass), contrary to relationships presented in the literature. Tree species richness and basal area were lower than for most similar types in Nepal. Biomass and productivity of the forests in Kumaun were relatively high, compared to mean values for similar forest types elsewhere. Measured values for most variables describing these forests (but not all) fell within the ranges for the variables in similar forests worldwide. The maximal values for forest biomass remained high, 500-600 Mg/ha, up to 2600 m elevation, but declined sharply in birch forest (_ 170 Mg/ha) above 3100 m. Net primary productivity (NPP) varied little (15-20 Mg* ha- I.yr- 1) below 2700 m, despite a 10WC gradient in mean annual temperature and marked changes in basal area, tree density, growth form, and leaf char- acters. The level of productivity appeared not to be limited by rainfall, forest structure, leaf type, or temperature above an annual mean of 1 PC. Leaf mass (LM) varied consid- erably among forest types, being 3.7-8.6 Mg/ha for deciduous species, 5.7-8.9 Mg/ha for P. roxburghii, and 10.0-28.2 Mg/ha for evergreen broad-leaved species. Leaf mass duration (leaf mass x months of the year with leaves present) was related directly to NPP and inversely to leaf production efficiency (NPP/LM). These data add substantially to the data base for forest properties, especially for broad-leaved evergreen forests.

[1]  Helmut Lieth,et al.  Primary Production of the Major Vegetation Units of the World , 1975 .

[2]  J. Singh,et al.  Estimation of biomass and nutrient storage in a Himalayan moist temperate forest , 1983 .

[3]  S. Singh,et al.  Dynamics of Nutrients and Leaf Mass in Central Himalayan Forest Trees and Shrubs. , 1987, Ecology.

[4]  P. Reich,et al.  Leaf Life‐Span in Relation to Leaf, Plant, and Stand Characteristics among Diverse Ecosystems , 1992 .

[5]  C. Monk Tree Species Diversity in the Eastern Deciduous Forest with Particular Reference to North Central Florida , 1967, The American Naturalist.

[6]  J. Singh,et al.  Replacement of oak forest with pine in the Himalaya affects the nitrogen cycle , 1984, Nature.

[7]  H. Lieth Modeling the Primary Productivity of the World , 1975 .

[8]  A. Shmida,et al.  Biological determinants of species diversity , 1985 .

[9]  B. S. Rana,et al.  Biomass and net primary productivity in Central Himalayan forests along an altitudinal gradient , 1989 .

[10]  J. Grace,et al.  Temperature and stature: a study of temperatures in montane vegetation , 1987 .

[11]  T. Fahey,et al.  Biomass and nutrients in an Engelmann spruce–subalpine fir forest in north central Colorado: pools, annual production, and internal cycling , 1992 .

[12]  D. Sprugel The Relationship of Evergreenness, Crown Architecture, and Leaf Size , 1989, American Naturalist.

[13]  K. Valdiya Geology of Kumaun Lesser Himalaya , 1980 .

[14]  Claude E. Shannon,et al.  The Mathematical Theory of Communication , 1950 .

[15]  Glenn M. Hawk,et al.  Relationships of Environment to Composition, Structure, and Diversity of Forest Communities of the Central Western Cascades of Oregon , 1976 .

[16]  Richard H. Waring,et al.  Forest Ecosystems: Concepts and Management , 1985 .

[17]  P. White,et al.  Biomass and production of southern Appalachian cove forests reexamined , 1993 .

[18]  K. Kikuzawa A Cost-Benefit Analysis of Leaf Habit and Leaf Longevity of Trees and Their Geographical Pattern , 1991, The American Naturalist.

[19]  J. A. Wolfe Temperature parameters of humid to mesic forests of Eastern Asia and relation to forests of other regions of the Northern Hemisphere and Australasia: analysis of temperature data from more than 400 stations in Eastern Asia , 1979 .

[20]  Manfred J. Müller Selected climatic data for a global set of standard stations for vegetation science , 1982, Tasks for vegetation science.

[21]  H. Mooney Biological Response to Climate Change: An Agenda for Research. , 1991, Ecological applications : a publication of the Ecological Society of America.

[22]  L. Webb,et al.  A Physiognomic Classification of Australian Rain Forests , 1959 .

[23]  S. Singh,et al.  High altitude forest: composition, diversity and profile structure in a part of Kumaun Himalaya. , 1991 .

[24]  J. V. Daalen Distinguishing features of forest species on nutrient-poor soils in the Southern Cape , 1984 .

[25]  D. Schmidt-Vogt High altitude forests in the Jugal Himal (eastern central Nepal): forest types and human impact. , 1992 .

[26]  A. Sakai,et al.  Winter Hardiness of Tree Species at High Altitudes in the East Himalaya, Nepal , 1981 .

[27]  David J. Hicks,et al.  The Ecology of Leaf Life Spans , 1982 .

[28]  E. K. Kalela Mäntysiemenpuiden ja -puustojen juurisuhteista. , 1954 .

[29]  J. Singh,et al.  The structure and function of pine forest in central Himalaya. I: Dry matter dynamics , 1987 .

[30]  Gene E. Likens,et al.  The Biosphere and Man , 1975 .

[31]  C. Prescott,et al.  Biomass, productivity, and nutrient-use efficiency of aboveground vegetation in four Rocky Mountain coniferous forests , 1989 .

[32]  A. Shmida,et al.  Measuring beta diversity with presence-absence data , 1984 .

[33]  J. Singh,et al.  Structure and Function of Oak Forests in Central Himalaya. I. Dry Matter Dynamics , 1988 .

[34]  R. Whittaker Evolution and measurement of species diversity , 1972 .

[35]  S. Singh,et al.  Forests of Himalaya: Structure, functioning, and impact of man , 1992 .

[36]  R. Schmid,et al.  Flowers of the Himalaya , 1985 .

[37]  I. Alexander,et al.  Methods of calculating fine root production in forests. , 1985 .