Join for Free!
114012 members
table of contents table of contents

When adapting forest management practices to a changing environment, it is very …

Biology Articles » Bioclimatology » Impact of climate change on radial growth of Siberian spruce and Scots pine in North-western Russia » References

- Impact of climate change on radial growth of Siberian spruce and Scots pine in North-western Russia

  1. Akaike H (1974). A new look at the statistical model identification. IEEE Transactions on Automatic Control AC-19: 716-723.
  2. Bartholomay GA, Eckert RT, Smith KT (1997). Reductions in tree-ring widths of white pine following ozone exposure at Acadia National Park, Maine, USA. Canadian Journal of Forest Research - Revue Canadienne de Recherche Forestiere 27: 361-368.
  3. Box GEP, Jenkins GM (1976). Time series analysis: Forecasting and control (revised edition). San Francisco, Holden-Day.
  4. Briffa KR, Schweingruber FH, Jones PD, Osborn TJ, Shiyatov SG, Vaganov EA (1998). Reduced sensitivity of recent tree-growth to temperature at high northern latitudes. Nature 391: 678-682.
  5. Carrer M, Urbinati C (2004). Age-dependent tree-ring growth responses to climate in Larix decidua and Pinus cembra. Ecology 85: 730-740.
  6. Cook ER (1985). A time series analysis approach to tree-ring standardization. University of Arizona, Tucson, pp. 171.
  7. Cook ER, Kairiukstis LA (1990). Methods of dendrochronology. Applications in the environmental sciences. International Institute of Applied System Analysis, Kluwer Academic Publishers, Dordrecht, The Netherlands.
  8. Da Motta RS (2004). Sustainable forest management and global climate change: Selected case studies from the Americas. Environment and Development Economics 9: 272-276.
  9. Drobyshev I, Niklasson M, Angelstam P (2004). Contrasting tree-ring data with fire record in a pine-dominated landscape in the Komi republic (Eastern European Russia): Recovering a common climate signal. Silva Fennica 38: 43-53.
  10. Galenko E (1983). Phytoclimate and ecological factors of increasing productivity of boreal forests in Russian European North. Nauka, Leningrad.
  11. Grissino-Mayer H, Holmes R, Fritts H (1997). International tree-ring data bank program library manual. Tucson, Arizona, Laboratory of Tree-Ring Research, University of Arizona.
  12. Helama S, Lindholm M, Timonen M, Merilainen J, Eronen M (2002). The supra-long Scots pine tree-ring record for Finnish Lapland: Part 2, inter-annual to centennial variability in summer temperatures for 7500 years. Holocene 12: 681-687.
  13. Holmes R (1999). Dendrochronology program library. User’s manual. Tucson, Arizona, USA, Laboratory of Tree-Ring Research, University of Arizona.
  14. IPCC (2001). Climate Change 2001: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change (Houghton JT, Ding Y, Griggs DJ, Noguer M, van der Linden PJ, Dai X, Maskell K, Johnson CA eds). Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 881.
  15. Jonsson B (1969). Studier över den avvä derleken orsakade variationen i å rsringsbredderna hos tall och gran i Sverige. 16, 1-279. Rapporter och Uppsatser, Institution for skogsproduction, Skogsh ö gskolan.
  16. Kalela-Brundin M (1999). Climatic information from tree-rings of Pinus sylvestris L. and a reconstruction of summer temperatures back to AD 1500 in Femundsmarka, eastern Norway, using partial least squares regression (PLS) analysis. Holocene 9: 59-77.
  17. Kellomaki S, Vaisanen H (1997). Modelling the dynamics of the forest ecosystem for climate change studies in the boreal conditions. Ecological Modelling 97: 121-140.
  18. Kellomaki S, Vaisanen H, Kolstrom T (1997). Model computations on the effects of elevating temperature and atmospheric CO2 on the regeneration of Scots pine at the timber line in Finland. Climatic Change 37: 683-708.
  19. Kellomaki S, Wang KY (1997a). Effects of elevated O3 and CO2 on chlorophyll fluorescence and gas exchange in Scots pine during the third growing season. Environmental Pollution 97: 17-27.
  20. Kellomaki S, Wang KY (1997b). Photosynthetic responses of Scots pine to elevated CO2 and nitrogen supply: Results of a branch-in-bag experiment. Tree Physiology 17: 231-240.
  21. Kirchhefer AJ (2001). Reconstruction of summer temperatures from tree-rings of Scots pine (Pinus sylvestris L.) in coastal northern Norway. Holocene 11: 41-52.
  22. Knowlton K, Rosenzweig C, Goldberg R, Lynn B, Gaffin S, Hogrefe C, Civerolo K, Ku JY, Solecki W, Small C, Oliveri C, Cox J, Rosenthal J, Kinney PL (2004). Evaluating global climate change impacts on local health across a diverse urban region. Epidemiology 15: S-100.
  23. Kozubov GM, Taskaev AI (1999). Forestry and forest resources of Komi Republic. Dik Publishing House, Moscow, Russia (in russian).
  24. Larin V (1997). Forests, their exploitation and regeneration. In: Republic of Komi. Komi Publishing House, Syktyvkar, Russia, pp. 34-40.
  25. Linderholm HW, Solberg BO, Lindholm M (2003). Tree-ring records from central Fennoscandia: the relationship between tree growth and climate along a west-east transect. Holocene 13: 887-895.
  26. Lindholm M (1996). Reconstruction of past climate from ring-width chronologies of Scots pine (Pinus sylvestris L.) at the northern forest limit in Fennoscandia. University of Joensuu, pp. 7-169.
  27. Lindholm M, Eronen M (2000). A reconstruction of mid-summer temperatures from ring-widths of Scots pine since AD 50 in northern Fennoscandia. Geografiska Annaler Series A-Physical Geography 82A: 527-535.
  28. Lopatin E, Kolstrom T, Spiecker H (2006). Determination of forest growth trends in Komi Republic (northwestern Russia): combination of tree-ring analysis and remote sensing data. Boreal Environment Research 11: 341-353.
  29. Makinen H, Nojd P, Kahle HP, Neumann U, Tveite B, Mielikainen K, Rohle H, Spiecker H (2003). Large-scale climatic variability and radial increment variation of Picea abies (L.) Karst. in central and northern Europe. Trees-Structure and Function 17: 173-184.
  30. Mauro G (2004). Observations on permafrost ground thermal regimes from Antarctica and the Italian Alps, and their relevance to global climate change. Global and Planetary Change 40: 159-167.
  31. Menzel A, Fabian P (1999). Growing season extended in Europe. Nature 397: 659.
  32. Meyneeke JO (2004). Effects of global climate change on geographic distributions of vertebrates in North Queensland. Ecological Modelling 174: 347-357.
  33. Miina J (2000). Dependence of tree-ring, earlywood and latewood indices of Scots pine and Norway spruce on climatic factors in eastern Finland. Ecological Modelling 132: 259-273.
  34. Miller CE (2003). Satellite observations of global climate change. Abstracts of Papers of the American Chemical Society 226: U23.
  35. Monserud RA (1986). Time-Series Analyses of Tree-Ring Chronologies. Forest Science 32: 349-372.
  36. Oberman NG, Mazhitova GG (2004). Permafrost dynamics in the north-east of European Russia at the end of the 20th century. Norwegian Journal of Geography 55: 241-244.
  37. Raspopov OM, Dergachev VA, Kolstrom T (2004). Periodicity of climate conditions and solar variability derived from dendrochronological and other palaeoclimatic data in high latitudes. Palaeogeography Palaeoclimatology Palaeoecology 209: 127-139.
  38. Razuvaev VN, Apasova EG, Martuganov RA (1995). Six- and Three-Hourly Meteorological Observations from 223 USSR Stations. ORNL/CDIAC-66, NDP-048. Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, Oak Ridge, Tennessee, USA.
  39. Spiecker H (1999). Overview of recent growth trends in European forests. Water Air and Soil Pollution 116: 33-46.
  40. Spiecker H (2000). Growth of Norway Spruce (Picea abies (L.) Karst.) under changing environmental conditions in Europe. In: Spruce Monocultures in Central Europe: Problems and Prospects (Klimo E, Hager H, Kulhavy J eds). European Forest Institute. European Forest Institute Proceedings 33, pp. 11-26.
  41. Spiecker H (2002). Tree rings and forest management in Europe. Dendrochronologia 20: 191-202.
  42. Stolpovski PM (1997). Republic of Komi. Komi Publishing House, Syktyvkar.
  43. Vaganov EA, Hughes MK, Kirdyanov AV, Schweingruber FH, Silkin PP (1999). Influence of snowfall and melt timing on tree growth in subarctic Eurasia. Nature 400: 149-151.
  44. Vose RS, Schmoyer RL, Steurer PM, Peterson TC, Heim R, Karl TR, Eischeid JK (1992). The Global Historical Climatology Network: Long-term monthly temperature, precepitation, sea level pressure and station pressure data. ORNL/CDIAC-53, NDP-041. Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, Oak Ridge, Tennessee, USA.
  45. Wager DJ, Baker FA (2003). Potential effects of ozone, climate, and spruce budworm on Douglas-fir growth in the Wasatch Mountains. Canadian Journal of Forest Research - Revue Canadienne de Recherche Forestiere 33: 910-921.
  46. Wigley TM, Briffa KR, Jones PD (1984). On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. Journal of Climate and Applied Meteorology 23: 201-213.
  47. Zagreev VV (1992). General yield tables for normal stands. In: Forest Inventory Handbook, all union rules and regulations for the forest inventory. Kolos, Moscow, pp. 298-231.

rating: 4.00 from 5 votes | updated on: 21 Nov 2007 | views: 11046 |

Rate article: