Drivers of productivity differences between Douglas-fir planted within its native range in Oregon and on exotic sites in New Zealand
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[1] David R. Carter,et al. Crown architecture, crown leaf area distribution, and individual tree growth efficiency vary across site, genetic entry, and planting density , 2019, Trees.
[2] H. Hasenauer,et al. Forest stand productivity derived from site conditions: an assessment of old Douglas-fir stands (Pseudotsuga menziesii (Mirb.) Franco var. menziesii) in Central Europe , 2019, Annals of Forest Science.
[3] M. Coleman,et al. Site sensitive maximum stand density index models for mixed conifer stands across the Inland Northwest, USA , 2019, Forest Ecology and Management.
[4] J. Stape,et al. A common garden experiment examining light use efficiency and heat sum to explain growth differences in native and exotic Pinus taeda , 2018, Forest Ecology and Management.
[5] C. Gonzalez-Benecke,et al. Use of water stress integral to evaluate relationships between soil moisture, plant water stress and stand productivity in young Douglas-fir trees , 2018, New Forests.
[6] J. Mikola,et al. Temperature and soil fertility as regulators of tree line Scots pine growth and survival—implications for the acclimation capacity of northern populations , 2018, Global change biology.
[7] J. Stape,et al. Incorporating rainfall data to better plan eucalyptus clones deployment in eastern Brazil , 2017 .
[8] H. Schielzeth,et al. The coefficient of determination R2 and intra-class correlation coefficient from generalized linear mixed-effects models revisited and expanded , 2016, bioRxiv.
[9] D. Peterson,et al. Increased water deficit decreases Douglas fir growth throughout western US forests , 2016, Proceedings of the National Academy of Sciences.
[10] Tongli Wang,et al. Locally Downscaled and Spatially Customizable Climate Data for Historical and Future Periods for North America , 2016, PloS one.
[11] N. Lazar,et al. The ASA Statement on p-Values: Context, Process, and Purpose , 2016 .
[12] F. Lebourgeois,et al. Stand density, tree social status and water stress influence allocation in height and diameter growth of Quercus petraea (Liebl.). , 2015, Tree physiology.
[13] P. Gould,et al. Climate‐related genetic variation in drought‐resistance of Douglas‐fir (Pseudotsuga menziesii) , 2015, Global change biology.
[14] D. Wardle,et al. Interactions with soil biota shift from negative to positive when a tree species is moved outside its native range. , 2014, The New phytologist.
[15] Thomas L. Eberhardt,et al. Relationships between climate, radial growth and wood properties of mature loblolly pine in Hawaii and a northern and southern site in the southeastern United States , 2013 .
[16] Annette Menzel,et al. Impact of climate and drought events on the growth of Scots pine (Pinus sylvestris L.) provenances , 2013 .
[17] J. Abatzoglou. Development of gridded surface meteorological data for ecological applications and modelling , 2013 .
[18] P. Gould,et al. Growth phenology of coast Douglas-fir seed sources planted in diverse environments. , 2012, Tree physiology.
[19] N. Crookston,et al. Projected future suitable habitat and productivity of Douglas-fir in western North America , 2012 .
[20] Maurizio Mencuccini,et al. Effects of climate and site characteristics on Scots pine growth , 2011, European Journal of Forest Research.
[21] K. Johnsen,et al. Maximum growth potential in loblolly pine: results from a 47-year-old spacing study in Hawaii , 2010 .
[22] G. R. Johnson,et al. Breeding Douglas‐Fir , 2010 .
[23] N. Coops,et al. Physiologically derived predictions of Douglas-fir site index in British Columbia , 2009 .
[24] V. P. Fadeeva,et al. Elemental analysis of organic compounds with the use of automated CHNS analyzers , 2008 .
[25] D. Whitehead,et al. Why is the productivity of Douglas-fir higher in New Zealand than in its native range in the Pacific Northwest, USA? , 2008 .
[26] A. Leckie,et al. Effect of boron fertiliser, weed control and genotype on foliar nutrients and tree growth of juvenile Pinus radiata at two contrasting sites in New Zealand , 2008 .
[27] G. Howe,et al. Genetic maladaptation of coastal Douglas‐fir seedlings to future climates , 2007 .
[28] Xiaogu Zheng,et al. Thin plate smoothing spline interpolation of daily rainfall for New Zealand using a climatological rainfall surface , 2006 .
[29] Nicholas C. Coops,et al. Predicting site index with a physiologically based growth model across Oregon, USA , 2005 .
[30] M. G. Ryan,et al. Eucalyptus production and the supply, use and efficiency of use of water, light and nitrogen across a geographic gradient in Brazil , 2004 .
[31] David R. Anderson,et al. Model Selection and Multimodel Inference , 2003 .
[32] N. McDowell,et al. Use of a physiological process model with forestry yield tables to set limits on annual carbon balances. , 2002, Tree physiology.
[33] R. Bailey,et al. Loblolly Pine—Pushing the Limits of Growth , 2001 .
[34] D. Olszyk,et al. Seasonal patterns of photosynthesis in Douglas fir seedlings during the third and fourth year of exposure to elevated CO2 and temperature , 2001 .
[35] T. Martin,et al. Ideotype Development in Southern Pines: Rationale and Strategies for Overcoming Scale-Related Obstacles , 2001, Forest Science.
[36] D. Bates,et al. Mixed-Effects Models in S and S-PLUS , 2001 .
[37] R. Waring,et al. A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning , 1997 .
[38] Roderick C. Dewar,et al. Carbon Allocation in Trees: a Review of Concepts for Modelling , 1994 .
[39] C. D. Whitesell,et al. Stand and tree characteristics and stockability in Pinus taeda plantations in Hawaii and South Carolina , 1994 .
[40] M. Benson,et al. Effects of combinations of irrigation and fertilisation on the growth and above-ground biomass production of Pinus radiata , 1992 .
[41] William R. Wykoff,et al. A Basal Area Increment Model for Individual Conifers in the Northern Rocky Mountains , 1990, Forest Science.
[42] R. Monserud,et al. Genetic and Environmental Components of Variation of Site Index in Inland Douglas-Fir , 1990, Forest Science.
[43] Steven W. Running,et al. Water/Nutrient Interactions Affecting the Productivity of Stands of Pinus radiata , 1990 .
[44] Martin W. Ritchie,et al. Equations for predicting basal area increment in Douglas-fir and grand fir , 1985 .
[45] David K. Walters,et al. Equations and tables predicting gross total stem volumes in cubic feet for six major conifers of southwest Oregon , 1985 .
[46] A. Mehlich. Mehlich 3 soil test extractant: A modification of Mehlich 2 extractant , 1984 .
[47] F. Smith,et al. The role of Douglas-fir stem sapwood and heartwood in the mechanical and physiological support of crowns and development of stem form , 1981 .
[48] J. Flewelling,et al. Stand Density Management: an Alternative Approach and Its Application to Douglas-fir Plantations , 1979 .
[49] G. M. Furnival. An index for comparing equations used in constructing volume tables , 1961 .
[50] E. Truog,et al. Boron Determination in soils and plants using the quinalizarin reaction. , 1939 .
[51] R. K. Hermann,et al. Douglas-fir: The Genus Pseudotsuga , 2014 .
[52] R Core Team,et al. R: A language and environment for statistical computing. , 2014 .
[53] Donald Arthur Horneck,et al. SOIL, PLANT AND WATER REFERENCE METHODS FOR THE WESTERN REGION 1 , 2005 .
[54] E. Cook,et al. Modeling the Differential Sensitivity of Loblolly Pine to Climatic Change Using Tree Rings , 1998 .
[55] J. Adams,et al. MICRONUTRIENT AND MACRONUTRIENT UPTAKE BY PINUS RADIATA, AND SOIL BORON FRACTIONS, AS AFFECTED BY ADDED NITROGEN AND BORON , 1995 .
[56] N. Ledgard,et al. Exotic trees in the Canterbury high country. , 1985 .
[57] J. Lassoie. Physiological activity in Douglas-fir , 1982 .
[58] K. Yoda,et al. Self-thinning in overcrowded pure stands under cultivated and natural conditions (Intraspecific competition among higher plants. XI) , 1963 .
[59] Jacobs,et al. The effect of wind sway on the form and development of Pinus radiata D. Don , 1954 .