nach oben

Erschienen in:

01.06.2019 | Original Paper

Microclimatic variations and their effects on photosynthetic efficiencies and lichen species distribution along elevational gradients in Garhwal Himalayas

verfasst von: Nayan Sahu, Shiv Naresh Singh, Pragya Singh, Shruti Mishra, Neha Karakoti, Rajesh Bajpai, Soumit K. Behera, Sanjeeva Nayaka, D. K. Upreti

Erschienen in: Biodiversity and Conservation | Ausgabe 8-9/2019

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Climate change effects on Himalayas are expectedly more pronounced than any other mountainous ecoregion of the world with expected threat of meltdown by the year 2100 if effective checks are not imposed. The impacts of this climate warming in the geologically fragile Himalayas has started to show its effects on shifting precipitation patterns, increasing temperatures, glaciers meltdown, species richness patterns and overall unpredictable microclimatic conditions. For measuring such impacts of current climate warming in Himalayan ecosystems, need of ecological substitutes has been stressed on by different United Nation conventions. Lichens in contrast to vascular flora have long been proved to act as cost effective global indicators for measuring ecosystems responses to environmental climate. The variations in microclimatic attributes and their effects on photosynthetic efficiency and distribution were studied in geologically fragile ecosystem of Govind Pashu Vihar National Park in Garhwal Himalayas. Total 217 species of lichens comprising 80 genera and 35 families were found along different elevations. Among the different habitat groups, corticolous lichens showed their dominance (123 species) followed by saxicolous (65 species) and terricolous (29 species) lichens. Corticolous forms were dominated by crustose while saxicolous and terricolous were mostly fruticose growth forms. Mostly large number of species showed a narrow distribution with maximum species richness observed in mid elevation zones (1950–2200 m) followed by a gradual decline towards higher elevations. Phaeophyscia hispidula, Parmotrema reticulatum and Flavoparmelia caperata showed wider ecological amplitude. Out of these species, P. hispidula and F. caperata were further subjected to chlorophyll fluorescence measurements with a pulse amplified modulated fluorometer to access photosynthetic quenching efficiencies. Maximum electron transport rates (ETR; 96 ± 5.76 μmol e⁻ m⁻² s⁻¹) were observed in Phaeophyscia hispidula (1550 m) while F. caperata showed nearly 21% lower ETR. Photochemical quenching (qP; 0.5 ± 0.01) was maximum at 1550 m elevation in F. caperata while P. hispidula showed maximum qP values at 2200 m elevation, showing it’s higher tolerances towards extreme light stresses. F. caperata showed higher (0.102 ± 0.003) non photochemical quenching (NPQ) in comparison to P. hispidula (0.062 ± 0.001) at extreme elevations of 3508 m. P. hispidula overall showed more toxitolerant nature towards abiotic stresses as compared to F. caperata. Higher photosynthetically active radiation (PAR; 1600–2350 µmol m⁻² s⁻¹), thallus hydration levels and extreme variations in air temperature (5.75–31.65 °C), ambient humidity along elevations were imperative in controlling species richness, distribution and photosynthetic quenching of lichen flora in the region.

Vorheriger Artikel Recent advances in biodiversity and climate change studies in India

Nächster Artikel Functional diversity along elevational gradients in the high altitude vegetation of the western Himalaya

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Nur mit Berechtigung zugänglich

Anderson MJ, Willis TJ (2003) Canonical analysis of principal coordinates: a useful method of constrained ordination for ecology. Ecology 84(2):511–525CrossRef

Asplund J, Wardle DA (2016) How lichens impact on terrestrial community and ecosystem properties. Biol Rev 92:1720–1738CrossRefPubMed

Austrheim G (2002) Plant diversity in semi-natural grasslands along an elevational gradient in southern Norway. Plant Ecol 161:193–205CrossRef

Awasthi DD (1988) A key to the macro lichens of India and Nepal. J Hattori Bot Lab 65:207–302

Awasthi DD (2000) Lichenology in India and subcontinents: a supplement to a handbook of lichens. Bishen Singh and Mahenderpal Singh, Dehradun

Awasthi DD (2007) A compendium of the macrolichens from India, Nepal, Srilanka. Bishen Singh and Mahenderpal Singh, Dehradun

Bajpai R, Semwal M, Singh CP (2018) Suitability of lichens to monitor climate change Cryptogam Biodiversity and Assessment. 2456–0251:182–189

Balaji P, Hariharan GN (2004) Lichen Diversity and its distribution pattern in tropical dry evergreen forest of Guindy National Park (GNP), Chennai. Indian For 130:1155–1168

Baniya CB (2010) Vascular and cryptogam richness in the world’s highest alpine zone, Tibet. Mt Res Dev 30:275–281CrossRef

Baniya CB, Solhøy T, Gauslaa Y, Palmer MW (2010) The elevation gradient of lichen species richness in Nepal. Lichenologist 42:83–96CrossRef

Baniya CB, Solhoy T, Gauslaa Y, Palmer MW (2012) Richness and composition of vascular plants and cryptogams along a high elevational gradient on Buddha mountain, central Tibet. Folia Geobot 47:135–151CrossRef

Barták M, Hájek J, Vráblíková H, Dubová J (2004) High-light stress and photoprotection in Umbilicaria antarctica monitored by chlorophyll fluorescence imaging and changes in zeaxanthin and glutathione. Plant Biol (Stuttg) 6(3):333–341CrossRef

Barták M, Solhaug KA, Vráblíková H, Gauslaa Y (2006) Curling during desiccation protects the foliose lichen Lobaria pulmonaria against photoinhibition. Oecologia 149:553–560CrossRefPubMed

Barták M, Hájek J, Morkusová J, Skácelová K, Košuthová A, Košuthová A (2018) Dehydration-induced changes in spectral reflectance indices and chlorophyll fluorescence of Antarctic lichens with different thallus color, and intra thalline photobiont. Acta Physiol Plant 40:177CrossRef

Behera SK, Mishra AK, Sahu N, Kumar A, Singh N, Kumar A, Bajpai O, Chaudhary LB, Khare PB, Tulil R (2012) The study of microclimate in response to different plant community association in tropical moist deciduous forest from northern India. Biodivers Conserv 21:1159–1176CrossRef

Belnap J, Gillette DA (1998) Vulnerability of desert biological soil crusts to wind erosion: the influences of crust development, soil texture, and disturbance. J Arid Environ 39:133–142CrossRef

Bhattarai KR, Vetaas OR (2003) Variation in plant species richness of different life forms along a subtropical elevation gradient in the Himalayas, east Nepal. Glob Ecol Biogeograp 12:327–340CrossRef

Bhattarai KR, Vetaas OR, Grytnes JA (2004) Fern species richness along a central Himalayan elevation gradient, Nepal. J Biogeogr 31:398–400. https://doi.org/10.1046/j.0305-0270.2003.01013.x CrossRef

Bruun HH, Moen J, Virtanen R, Grytnes JA, Oksanen L, Angerbjörn A (2006) Effects of altitude and topography on species richness of vascular plants, bryophytes and lichens in alpine communities. J Veg Sci 17:37–46CrossRef

Castello M, Skert N (2005) Evaluation of lichen diversity as an indicator of environmental quality in the North Adriatic sub-mediterranean region. Sci Total Environ 336:201–214CrossRefPubMed

Chawla A, Rajkumar S, Singh KN, Lal B, Singh RD, Thukral AK (2008) Plant species diversity along an altitudinal gradient of Bhabha Valley in western Himalaya. J Mt Sci 5(2):157–177CrossRef

Cocchietto M, Skert N, Nimis P, Sava G (2002) A review on usnic acid, an interesting natural compound. Naturwissenschaften 89:137–146CrossRefPubMed

Connell JH (1978) Diversity in tropical rainforests and coral reefs. Science 199:1302–1310CrossRefPubMed

Cornelissen JHC, Callaghan TV, Alatalo JM, Michelsen A, Graglia E, Hartley AE, Hik DS, Hobbie SE, Press MC, Robinson CH, Henry GHR, Shaver GR, Phoenix GK, Jones DG, Jonasson S, Chapin FS, Molau U, Neill C, Lee JA, Melillo JM, Sveinbjörnsson B, Aerts R (2001) Global change and arctic ecosystems: is lichen decline a function of increases in vascular plant biomass? J Ecol 89:984–994CrossRef

Cowan IR, Lange OL, Green TGA (1992) Carbon-dioxide exchange in lichens: determination of transport and carboxylation characteristics. Planta 187:282–294CrossRefPubMed

Dahlman L, Palmqvist K (2003) Growth in two foliose tripartite lichens, Nephroma arcticum and Peltigera aphthosa: empirical modeling of external vs internal; factors. Func Ecol 17:821–831CrossRef

Eldridge DJ, Tozer ME (1997) Environmental factors relating to the distribution of terricolous bryophytes and lichens in semi-arid eastern Australia. Bryologist 100:28–39CrossRef

Elix JA, Ernst-Russell KD (1993) A catalogue of standardized thin layer chromatographic data and biosynthetic relationships for lichen substances. Australian National University, Canberra

Gauslaa Y (2014) Rain, dew, and humid air as drivers of morphology, function and spatial distribution in epiphytic lichens. Lichenologist 46(1):1–16CrossRef

Gauslaa Y, Solhaug KA (1996) Differences in the susceptibility to light stress between epiphytic lichens of ancient and young boreal forest stands. Funct Ecol 10:344–354CrossRef

Gauslaa Y, Solhaug KA (1999) High-light damage in air-dry thalli of the old forest lichen Lobaria pulmonaria–interactions of irradiance, exposure duration and high temperature. J Exp Bot 50:697–705. https://doi.org/10.1093/jxb/50.334.697 CrossRef

Gauslaa Y, Kopperud C, Solhaug KA (1996) Optimal quantum yield of photosystem II and chlorophyll degradation of Lobaria pulmonaria in relation to pH. Lichenol 28:267–278. https://doi.org/10.1017/S0024282996000333 CrossRef

Gilmore AM (1997) Mechanistic aspects of xanthophyll cycle-dependent photo protection. Physiol Plant 99:197–209. https://doi.org/10.1111/j.1399-3054.1997.tb03449.x CrossRef

Gradstein SR, Pocs T (1989) Bryophytes. In: Lieth H, Werger MJA (eds) Tropical Rain Forest Ecosystems. Elsevier, Amsterdam, pp 311–325CrossRef

Grau O, Grytnes JA, Birks HJB (2007) A comparison of altitudinal species richness patterns of bryophytes with other plant groups in Nepal, Central Himalaya. J Biogeogr 34:1907–1915CrossRef

Green TGA, Lange OL, Cowan IR (1994) Ecophysiology of lichen photosynthesis, the role of water status and thallus diffusion resistances. Crypt Bot 4:166–178

Grytnes JA (2003) Species-richness patterns of vascular plants along seven altitudinal transects in Norway. Ecography 26:291–300CrossRef

Grytnes JA, Vetaas OR (2002) Species richness and altitude: a comparison between null models and interpolated plant species richness along the Himalayan altitudinal gradient, Nepal. Am Nat 159:294–304CrossRefPubMed

Grytnes JA, Heegaard E, Ihlen PG (2006) Species richness of vascular plants, bryophytes, and lichens along an altitudinal gradient in western Norway. Acta Oecol 29:241–246CrossRef

Hammer Ø, Harper DAT, Ryan PD (2001) PAST: Paleontological statistics software package for education and data analysis. Palaeontologia Electronica 4(1):1–9

Hampp R, Cardoso N, Fleig M, Grüninger W (2018) Vitality of lichens under different light climates in an Araucaria forest (Pró-mata RS, south Brazil) as determined by chlorophyll fluorescence. Acta Bot Bras 32:188–197CrossRef

Hauck M, Jürgens SR (2008) Usnic acid controls the acidity tolerance of lichens. Environ Pollut 156:115–122CrossRefPubMed

Hauck M, Helms G, Friedl T (2007) Photobiont selectivity in the epiphytic lichens Hypogymnia physodes and Lecanora conizaeoides. Lichenologist 39:195–204CrossRef

Hunter ML, Yonzon P (1993) Altitudinal distributions of birds, mammals, people, forests, and parks in Nepal. Conserv Biol 7:420–423CrossRef

IPCC, Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (2014) Climate change 2014: synthesis report. IPCC, Cambridge University Press, Geneva

Jensen M, Kricke R (2000) Chlorophyll fluorescence measurements in the field: assessment of the vitality of large numbers of lichen thalli. In: Nimis PL, Scheidegger C, Wolseley A (eds) Monitoring with lichens—monitoring lichens, NATO science series IV: earth and environmental sciences 7. Kluwer, Dordrecht

John E, Dale MRT (1990) Environmental correlates of species distributions in a saxicolous lichen community. J Veg Sci 1:385–392CrossRef

Jüriado I, Liira J, Paal J, Suija A (2009) Tree and stand level variables influencing diversity of lichens on temperate broad-leaved trees in boreo-nemoral floodplain forests. Biodivers Conserv 18:105–125CrossRef

Karakoti N, Bajpai R, Upreti DK, Mishra GK, Srivastava A, Nayaka S (2014) Effect of metal content on chlorophyll fluorescence and chlorophyll degradation in lichen Pyxine cocoes (Sw.) Nyl.: a case study from Uttar Pradesh, India. Environ Earth Sci 71:2177–2183CrossRef

Kershaw KA (1972) The relationship between moisture content and net assimilation rate of lichen thalli and its ecological significance. Can J Bot 50:543–555CrossRef

Kessler M (2000) Elevational gradients in species richness and endemism of selected plant groups in the central Bolivian Andes. Plant Ecol 149:181–193CrossRef

Kricke R, Loppi S (2002) Bioindication: the I.A.P. approach. In: Nimis PL, Scheidegger C, Wolseley PA (eds) Monitoring with lichens—monitoring lichens. Kluwer Academic Publishers, Dordrecht, pp 21–37CrossRef

Lang GE, Reiners WA, Pike LH (1980) Structure and biomass dynamics of epiphytic lichen communities of Balsam Fir Forests in New Hampshire. Ecology 61:541–550CrossRef

Lange OL, Tenhunen JD (1981) Moisture content and C02 exchange of lichens. II. Depression of net photosynthesis in Ramalina maciformis at high water content is caused by increased thallus carbon dioxide diffusion resistance. Oecologia 51:426–429CrossRefPubMed

Lange OL, Green TGA, Reichenbergerh H, Meyer A (1996) Photosynthetic depression at high thallus water content in lichens: concurrent use of gas exchange and fluorescence techniques with a cyanobacterial and a green algal Peltigera species. Bot Acta 109:43–50CrossRef

Lange OL, Leisner JMR, Bilger W (1999) Chlorophyll fluorescence characteristics of the cyanobacterial lichen peltigera rufescens under field conditions. II. Diel and annual distribution of metabolic activity and possible mechanisms to avoid photoinhibition. Flora 194(4):413–430CrossRef

Lange OL, Budel B, Meyer A, Zellner H, Zotz G (2000) Lichen carbon gain under tropical conditions: water relations and CO exchange of three Leptogium species of a lower montane rainforest in Panama. Flora 195:172–190CrossRef

Lawrey JD (1991) Biotic interactions in lichen community development: a review. Lichenologist 23:205–214CrossRef

Lehmkuhl JF (2004) Epiphytic lichen diversity and biomass in low-elevation forests of the eastern Washington Cascade range, USA. For Ecol Manage 187:381–392CrossRef

Li XP, Björkman O, Shih C, Grossman AR, Rosenquist M, Jansson S, Niyogi KK (2000) A pigment-binding protein essential for regulation of photosynthetic light harvesting. Nature 403:391–395CrossRefPubMed

Lieberman D, Lieberman M, Peralta R, Hartshorn GS (1996) Tropical forest structure and composition on a large-scale altitudinal gradient in Costa Rica. J Ecol 84:137–152CrossRef

Manrique E, Balaguer L, Barnes J, Davison AW (1993) Photoinhibition studies in lichens using chlorophyll fluorescence analysis. Bryologist 96:443–449CrossRef

Matos P, Geiser L, Hardman A et al (2017) Tracking global change using lichen diversity: towards a global-scale ecological indicator. Methods Ecol Evol 8:788–798CrossRef

Matveyeva N, Chernov Y (2000) Biodiversity of terrestrial ecosystems. In: Callaghan TV (ed) The arctic: environment, people, policy. Harwood Academic Publishers, New York, pp 233–274

Maxwell K, Johnson GN (2000) Chlorophyll fluorescence—a practical guide. J Exp Bot 51:659–668CrossRefPubMed

McCain CM (2004) The mid-domain effect applied to elevational gradients: species richness of small mammals in Costa Rica. J Biogeogr 3:19–31CrossRef

McCune B, Geiser L (1997) Macrolichens of the Pacific Northwest. Oregon State University Press, Corvallis, OR

Miehe G (1989) Vegetation patterns in Mount Everest as influenced by monsoon and föhn. Vegetation 79:21–32CrossRef

Mellin C, Delean S, Caley J et al (2011) Effectiveness of biological surrogates for predicting patterns of marine biodiversity: a global meta-analysis. PLoS ONE 6:e20141CrossRefPubMedPubMedCentral

Moritz C, Patton JL, Conroy CJ, Parra JL, White GC, Beissinger SR (2008) Impact of a century of climate change on small-mammal communities in Yosemite National Park, USA. Science 322:261–264CrossRefPubMed

Murchie EH, Lawson T (2013) Chlorophyll fluorescence analysis: a guide to good practice and understanding some new applications. J Exp Bot 13:3983–3998CrossRef

Nash TH (1996) Lichen biology. Cambridge University Press, Cambridge

Nash TH (2008) Lichen biology. Cambridge University Press, CambridgeCrossRef

Nayaka S, Upreti DK, Divakar PK (2001) Distribution and diversity of lichens in Meghamalai Wildlife Sanctuary, Kambam District, Tamil Nadu, India. Biol Mem 27:51–58

Negi HR (2000) On the patterns of abundance and diversity of macrolichens of Chopta-Tungnath in Garhwal Himalaya. J Biosci 25:367–378CrossRefPubMed

Negi HR, Gadgil M (1996) Patterns of distribution of macrolichens in Western parts of Nanda Devi Biosphere Reserve. Curr Sci 71:568–575

Negi HR, Upreti DK (2000) Species diversity and relative abundance of lichens in Rumbak catchment of Hemis National Park in Ladakh. Curr Sci 78:1105–1112

Nunes L, Burle G, Gumboski EL, Dechoum M (2018) Abiotic effects on the cover and richness of corticolous lichens on Araucaria angustifolia trunks. Acta Bot Bras. https://doi.org/10.1590/0102-33062018abb0095 CrossRef

Orange A, James PW, White FJ (2001) Microchemical methods for the identification of lichens. British Lichen Society, London

Palmquist K (2000) Carbon economy in lichens. New Phytol 148:11–36CrossRef

Paoli L, Pisani T, Munzi S, Gaggi C, Loppi S (2010) Influence of sun irradiance and water availability on lichen photosynthetic pigments during a Mediterranean summer. Biologia 65:776–783CrossRef

Pinokiyo A, Singh KP, Singh JS (2006) Leaf-colonizing lichens: their diversity, ecology and future prospects. Curr Sci 90:509–518

Pintado A, Sancho LG, Valladares F (2001) The influence of microclimate on the composition of lichen communities along an altitudinal gradient in the maritime Antarctic. Symbiosis 31:69–84

Ponzetti JM, McCune BP (2001) Biotic soil crusts of Oregon’s shrub steppe: community composition in relation to soil chemistry, climate and livestock activity. Bryologist 104:212–225CrossRef

Rai H, Khare R, Gupta RK, Upreti DK (2012) Terricolous lichens as indicator of anthropogenic disturbances in a high altitude grassland in Garhwal (Western Himalaya), India. Bot Orient 8:16–23CrossRef

Rai H, Khare R, Baniya CB, Upreti DK, Gupta RK (2014) Elevational gradients of terricolous lichen species richness in the Western Himalaya. Biodivers Conserv 24:1155–1174CrossRef

R Core Team (2018) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.R-project.org/

Rodriguez JM, Renison D, Filippini E, Estrabou C (2017) Small shifts in microsite occupation could mitigate climate change consequences for mountain top endemics: a test analyzing saxicolous lichen distribution patterns. Biodivers Conserv 26:1199–1215CrossRef

Rubio-Salcedo M, Psomas A, Prieto M, Zimmermann NE, Martínez I (2017) Case study of the implications of climate change for lichen diversity and distributions. Biodivers Conserv 26:1121–1141CrossRef

Scheidegger C, Schroeter B, Frey B (1995) Structural and functional processes during water vapour uptake and desiccation in selected lichens with green algal photobionts. Planta 197:399–409CrossRef

Sehnal L, Barták M, Váczi P (2014) Diurnal changes in photosynthetic activity of the biological soil crust and lichen: effects of abiotic factors (Petuniabukta, Svalbard). Czech Polar Rep 4(2):158–167CrossRef

Selva SB (1994) Lichen diversity and stand continuity in the northern hardwoods and spruce-fir forests of northern New England and western New Brunswick. Bryologist 97:424–429CrossRef

Sharma CM, Baduni NP, Gairola S, Ghildiyal SK, Suyal S (2010) Effects of slope aspects on forest compositions, community structures and soil properties in natural temperate forests of Garhwal Himalaya. J For Res 21:331–337CrossRef

Sheard JW, Jonescu ME (1974) A multivariate analysis of the distribution of lichens on Populus tremuloides in West-Central Canada. Bryologist 77:514CrossRef

Shrader DG (2011) Understanding the Relationship between Light Availability and Epiphytic Lichen Ecology: Canopy Openness, Photosynthetically Active Radiation, and the Role of the Host Tree Species. BIOS 35502: Practicum in Field Biology. pp 1–16

Shukla V, Upreti DK, Bajpai R (2014) In: Lichens to biomonitor the environment. Springer, New YorkCrossRef

Singh JS, Singh SP (1987) Forest vegetation of the Himalaya. Bot Rev 53:80–192CrossRef

Singh KP, Sinha GP (1997) Lichens. In: Mudgal V, Hajra PK (eds) Floristic diversity and conservation strategies in India. Botanical Survey of India, Kolkata, pp 195–234

Singh KP, Sinha GP (2010) Indian lichens: an annotated checklist. Govt. of India, Botanical Survey of India. Ministry of Environment and Forest, India

Summers DM, Bryan BA, Crossman ND, Meyer WS (2012) Species vulnerability to climate change: impacts on spatial conservation priorities and species representation. Glob Change Biol 18:2335–2348CrossRef

ter Braak CJF, Verdonschot PFM (1995) Canonical correspondence analysis and related multivariate methods in aquatic ecology. Aquat Sci 57:255–289CrossRef

Upreti DK, Divakar PK (2003) Distribution of lichens in Corbett Tiger Reserve, Uttaranchal. J Econ Taxon Bot 27:1043–1060

Upreti DK, Negi HR (1995) Lichens of Nanda Devi Biosphere Reserve, Uttar Pradesh, India. J Econ Taxon Bot 19:627–636

Valladares F, Sanchez-Hoyos A, Manrique E (1995) Diurnal changes in photosynthetic efficiency and carotenoid composition of the lichen Anaptychia ciliaris: effects of hydration and light intensity. Bryologist 98:375–382CrossRef

Vetaas OR, Grytnes JA (2002) Distribution of vascular plant species richness and endemic richness along the Himalayan elevation gradient in Nepal. Glob Ecol Biogeograp 11:291–301CrossRef

VonHaller A (1742) Enumeratio methodica stirpium Helvetiae indigenarum. A. Vanderhoek, Gottingae, DE

Walker FJ, James PW (1980) A revised guide to microchemical techniques for the identification of lichen products. Br Lichen Soc Bull 46((Supplement)):13–29

Wangda P, Ohsawa M (2006) Gradational forest change along the climatically dry valley slopes of Bhutan in the midst of humid Eastern Himalaya. Plant Ecol 186:109–128CrossRef

Whittaker RH (1960) Vegetation of the Siskiyou mountains, Oregon and California. Ecol Monogr 30:279–338CrossRef

Whittaker RH, Niering WA (1975) Vegetation of the Santa Catalina mountains, Arizona. V. Biomass, production, and diversity along the elevation gradient. Ecology 56:771–790CrossRef

Wilson RJ, Gutiérrez D, Gutiérrez J, Martínez D, Agudo R, Monserrat VJ (2005) Changes to the elevational limits and extent of species ranges associated with climate change. Ecol Lett 8:1138–1146CrossRefPubMed

Titel: Microclimatic variations and their effects on photosynthetic efficiencies and lichen species distribution along elevational gradients in Garhwal Himalayas
verfasst von: Nayan Sahu
Shiv Naresh Singh
Pragya Singh
Shruti Mishra
Neha Karakoti
Rajesh Bajpai
Soumit K. Behera
Sanjeeva Nayaka
D. K. Upreti
Publikationsdatum: 01.06.2019
Verlag: Springer Netherlands
Erschienen in: Biodiversity and Conservation / Ausgabe 8-9/2019
Print ISSN: 0960-3115
Elektronische ISSN: 1572-9710
DOI: https://doi.org/10.1007/s10531-019-01782-z

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 8-9/2019

Predicting invasion potential and niche dynamics of Parthenium hysterophorus (Congress grass) in India under projected climate change

Modeling net primary productivity of tropical deciduous forests in North India using bio-geochemical model

Modelling Betula utilis distribution in response to climate-warming scenarios in Hindu-Kush Himalaya using random forest

Pattern of distribution of angiosperm plant richness along latitudinal and longitudinal gradients of India

Assessing vulnerability of forest ecosystem in the Indian Western Himalayan region using trends of net primary productivity

Deciphering plant richness using satellite remote sensing: a study from three biodiversity hotspots