nach oben

Mitigation and Adaptation Strategies for Global Change

Erschienen in:

01.02.2016

Mitigation potential of important farm and forest trees: a potentiality for clean development mechanism afforestation reforestation (CDM A R) project and reducing emissions from deforestation and degradation, along with conservation and enhancement of carbon stocks (REDD+)

verfasst von: Rajiv Pandey, Sanjeet Kumar Hom, Steve Harrison, Vinod Kumar Yadav

Erschienen in: Mitigation and Adaptation Strategies for Global Change | Ausgabe 2/2016

Einloggen, um Zugang zu erhalten

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

search-config

KI-gestützte Suche

Aus

Abstract

The effectiveness and integrity of forest-based emissions reduction schemes such as Clean Development Mechanism Afforestation Reforestation (CDM A R) project and Reducing Emissions from Deforestation and Degradation (REDD+), along with conservation and enhancement of carbon (C) stocks implementation and assessment in developing countries are required not only, the appropriate monitoring and evaluation, rather the precise values of constants being used to estimate the C stocks or C credit in place of default or guess value. Estimates are reported of the C content of wood of four forest species (Shorea robusta, Pinus roxburghii, Tectona grandis and Cinnamomum camphora) and two important farm species (Populus deltoides and Eucalyptus treticornis) in the temperate region of Indian Himalayas, derived using the ash content method. These species were considered keeping in view of their potentiality for the C sequestration and storage projects across the developing countries specifically the South East Asian Countries. The specific gravity, ash content and C proportion is estimated for these six species by selecting random woods pieces. These estimates are designed to improve the calculations of biomass C for use in estimation of C credits in the developing region under CDM A R projects and REDD+ program supported by developed country. Regression analysis of C prediction models revealed that, for all six species, C content may be estimated through specific gravity of the wood by a linear equation without intercept. Indirectly, this results also implies that among the two farm trees, eucalyptus has high potentiality for C capturing and among four forest trees, Shorea robusta has high potentiality, therefore these two should have preference for plantation/regeneration as well as for conservation.

Vorheriger Artikel Adaptive management of marine mega-fauna in a changing climate

Nächster Artikel Impact of climate change on regional irrigation water demand in Baojixia irrigation district of China

Atjay GL, Ketner P, Duvigneaud P (1979) Terrestrial primary production and phytomass. In: Bolin B, Degens ET, Kempe S, Ketner P (eds) The global cycle. Wiley, Chichester

Bowen HLM (1979) Environmental chemistry of the elements. Academic, London

Brown S (1997) Estimating biomass and biomass change of tropical forests: a primer. FAO forestry paper 134. FAO, Rome

Bureau of Indian Standards (1986) IS: 1708 - methods of testing of small clear specimens of timber parts 1–18. BSI, New Delhi

Chhabra A, Dadhwal VK (2004) Assessment of major pools and fluxes of carbon in Indian forests. Clim Chang 64(3):341–360CrossRef

Dhand V, Tripathi AK, Manhas RK, Negi JDS, Chauhan PS (2003) Estimation of carbon content in some forest tree species. Indian Forester 129(7):918–922

Ehrman T (1994) Standard method for ash in biomass. LAP-005, chemical analysis and testing task laboratory analytical procedure. Department of Energy, Midwest Research Institute, Kansas

Flugsrud K, Hoem B, Kvingedal E, Rypdal K (2001) Estimating the net emission of CO₂ from harvested wood products: a comparison between different approaches. Norwegian Pollution Control Authority, Oslo

FSI (2011) India State of Forest Survey Report, 2011. Forest Survey of India (FSI), Dehradun, India

IPCC (2006) Good practice guidance for land use, land-use change, and forestry. IPCC, Geneva

Kishwan J, Pandey R, Dadhwal VK (2009) India’s Forest and tree cover: contribution as a carbon sink. BL-30, Indian Council of Forestry Research and Education, Dehradun

Ludwig J, Marufu LT, Huber B, Andreae MO, Hela G (2003) Domestic combustion of biomass fuels in developing countries: a major source of atmospheric pollutants. J Atmos Chem 44(1):23–37CrossRef

Miles PD, Smith WB (2009) Specific gravity and other properties of wood and bark for 156 tree species found in North America. Res. Note NRS-38. Department of Agriculture, Forest Service, Northern Research Station, Newtown Square, p 35

Namm BH, Berrill JP (2011) Accounting for variation in root wood density and percent carbon in belowground carbon estimates. General technical report PSW-GTR-19x. Humboldt State University, 1 Harpst St, Arcata

Negi JDS, Manhas RK, Chauhan PS (2003) Carbon allocation in different components of some tree species of India: a new approach for carbon estimation. Curr Sci 85(11):1528–1531

Rajput SS, Shukla NK, Gupta VK (1985) Specific gravity of Indian timbers. J Timber dev Assoc 31(3):12–43

Ramachandran A, Jayakumar S, Mohamed Haroon AR, Bhaskaran A (2007) Carbon management in forest floor- an agenda of 21st century in Indian forestry scenario. Indian Forester 133(1):25–40

Ravindranath NH, Somashekhar BS, Gadgil M (1997) Carbon flows in Indian forests. Climate Change 35(3):297–320CrossRef

Ravindranath NH, Chaturvedi RK, Murthy IK (2008) Forest conservation, afforestation and reforestation in India: implications for forest carbon stocks. Curr Sci 95(2):216–222

Richards JF, Flint EP (1994) Historic land use and carbon estimates for South and Southeast Asia 1880–1980. ORNL/CDIAC-61, NDP-046. Oak Ridge National Laboratory, Tennessee

Saugier B, Roy J (2001) Estimations of global terrestrial productivity; converging towards a single number? In: Roy J, Saugier B, Mooney HA (eds) Global terrestrial productivity: past, present and future. Academic, New York

Simpson WT (1993) Specific gravity, moisture content, and density relationship for wood. Forest products laboratory, general technical report FPL-GTR-76. USDA, Forest Services, FPL, Madison

Walkley A, Black IA (1934) An examination of the Degtjareff method for determining organic carbon in soils: effect of variations in digestion conditions and of inorganic soil constituents. Soil Sci 63:251–263CrossRef

Williamson GB, Wiemann MC (2010) Measuring wood specific gravity correctly. Am J Bot 97(3):519–524CrossRef

Ximenes FA (2007) Forests, wood and Australia’s carbon balance. cooperative research centre for greenhouse accounting. Australian National University, Canberra

Zhang SY (1997) Wood specific gravity-mechanical property relationship at species level. Wood Sci Technol 31(3):181–191

Titel: Mitigation potential of important farm and forest trees: a potentiality for clean development mechanism afforestation reforestation (CDM A R) project and reducing emissions from deforestation and degradation, along with conservation and enhancement of carbon stocks (REDD+)
verfasst von: Rajiv Pandey
Sanjeet Kumar Hom
Steve Harrison
Vinod Kumar Yadav
Publikationsdatum: 01.02.2016
Verlag: Springer Netherlands
Erschienen in: Mitigation and Adaptation Strategies for Global Change / Ausgabe 2/2016
Print ISSN: 1381-2386
Elektronische ISSN: 1573-1596
DOI: https://doi.org/10.1007/s11027-014-9591-2

Springer Professional

Abstract

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

Weitere Artikel der Ausgabe 2/2016

Economic and environmental effects of unilateral climate actions

Adaptation strategies to combat climate change effect on rice and mustard in Eastern India

Adaptive management of marine mega-fauna in a changing climate

Multilateral energy lending and urban bias in autocracies: promoting fossil fuels

Impact of climate change on regional irrigation water demand in Baojixia irrigation district of China

A framework for assessing vulnerability of inland fisheries to impacts of climate variability in India