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  1. 1
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  2. 2
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  3. 3
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  4. 4
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  5. 5
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  6. 6
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  7. 7
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  8. 8
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  9. 9
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  12. 12
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  13. 13
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  14. 14
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  15. 15
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  16. 16
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  17. 17
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  18. 18
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  19. 19
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  20. 20
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  21. 21
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  22. 22
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  23. 23
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  24. 24
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  25. 25
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  26. 26
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  27. 27
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  28. 28
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  29. 29
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  30. 30
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  31. 31
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  32. 32
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  33. 33
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  34. 34
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  35. 35
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  36. 36
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  37. 37
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    CrossRef

  38. 38
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  39. 39
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  40. 40
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  41. 41
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  42. 42
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    CrossRef

  43. 43
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  44. 44
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    CrossRef

  45. 45
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  46. 46
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    CrossRef

  47. 47
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  48. 48
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    CrossRef

  49. 49
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  50. 50
    F. Azam, S. Gill, S. Farooq, A. Lodhi, Effect of CO2 on nitrification and immobilization of NH4+-N, Biology and Fertility of Soils, 2004, 40, 6, 427

    CrossRef

  51. 51
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    CrossRef

  52. 52
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  53. 53
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  54. 54
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  55. 55
    Hendrik Poorter, Marie-Laure Navas, Plant growth and competition at elevated CO2: on winners, losers and functional groups, New Phytologist, 2003, 157, 2
  56. 56
    D. W. Johnson, B. A. Hungate, P. Dijkstra, G. Hymus, C. R. Hinkle, P. Stiling, B. G. Drake, THE EFFECTS OF ELEVATED CO2ON NUTRIENT DISTRIBUTION IN A FIRE-ADAPTED SCRUB OAK FOREST, Ecological Applications, 2003, 13, 5, 1388

    CrossRef

  57. 57
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  58. 58
    John J Dilustro, Frank P Day, Bert G Drake, Charles R Hinkle, Abundance, production and mortality of fine roots under elevated atmospheric CO2 in an oak-scrub ecosystem, Environmental and Experimental Botany, 2002, 48, 2, 149

    CrossRef

  59. 59
    Graham J. Hymus, Tom G. Snead, David P. Johnson, Bruce A. Hungate, Bert G. Drake, Acclimation of photosynthesis and respiration to elevated atmospheric CO2 in two Scrub Oaks, Global Change Biology, 2002, 8, 4
  60. 60
    Jean E. T. McLain, Thomas B. Kepler, Dianne M. Ahmann, Belowground factors mediating changes in methane consumption in a forest soil under elevated CO2, Global Biogeochemical Cycles, 2002, 16, 3
  61. 61
    Paul Dijkstra, Graham Hymus, Debra Colavito, David A. Vieglais, Christina M. Cundari, David P. Johnson, Bruce A. Hungate, C. ROSS Hinkle, Bert G. Drake, Elevated atmospheric CO2 stimulates aboveground biomass in a fire-regenerated scrub-oak ecosystem, Global Change Biology, 2002, 8, 1
  62. 62
    S.A Billings, S.M Schaeffer, R.D Evans, Trace N gas losses and N mineralization in Mojave desert soils exposed to elevated CO2, Soil Biology and Biochemistry, 2002, 34, 11, 1777

    CrossRef

  63. You have free access to this content63
    Mark D. Hunter, Effects of elevated atmospheric carbon dioxide on insect–plant interactions, Agricultural and Forest Entomology, 2001, 3, 3
  64. 64
    John J. Dilustro, Frank P. Day, Bert G. Drake, Effects of elevated atmospheric CO2 on root decomposition in a scrub oak ecosystem, Global Change Biology, 2001, 7, 5
  65. 65
    R. J. Lodge, P. Dijkstra, B. G. Drake, J. I. L. Morison, Stomatal acclimation to increased CO2 concentration in a Florida scrub oak species Quercus myrtifolia Willd, Plant, Cell & Environment, 2001, 24, 1
  66. 66
    G. J. Hymus, P. Dijkstra, N. R. Baker, B. G. Drake, S. P. Long, Will rising CO2 protect plants from the midday sun? A study of photoinhibition of Quercus myrtifolia in a scrub-oak community in two seasons, Plant, Cell & Environment, 2001, 24, 12
  67. 67
    Marcus Schortemeyer, Paul Dijkstra, Dale W. Johnson, Bert G. Drake, Effects of elevated atmospheric CO2 concentration on C and N pools and rhizosphere processes in a Florida scrub oak community, Global Change Biology, 2000, 6, 4