SEARCH

SEARCH BY CITATION

Cited in:

CrossRef

This article has been cited by:

  1. 1
    G. Larson, D. R. Piperno, R. G. Allaby, M. D. Purugganan, L. Andersson, M. Arroyo-Kalin, L. Barton, C. Climer Vigueira, T. Denham, K. Dobney, A. N. Doust, P. Gepts, M. T. P. Gilbert, K. J. Gremillion, L. Lucas, L. Lukens, F. B. Marshall, K. M. Olsen, J. C. Pires, P. J. Richerson, R. Rubio de Casas, O. I. Sanjur, M. G. Thomas, D. Q. Fuller, Current perspectives and the future of domestication studies, Proceedings of the National Academy of Sciences, 2014, 111, 17, 6139

    CrossRef

  2. 2
    Salvador Aljazairi, Claudia Arias, Elena Sánchez, Gladys Lino, Salvador Nogués, Effects of pre-industrial, current and future [CO2] in traditional and modern wheat genotypes, Journal of Plant Physiology, 2014, 171, 17, 1654

    CrossRef

  3. 3
    Gohar Ayub, Joana Zaragoza-Castells, Kevin L. Griffin, Owen K. Atkin, Leaf respiration in darkness and in the light under pre-industrial, current and elevated atmospheric CO2 concentrations, Plant Science, 2014, 226, 120

    CrossRef

  4. 4
    A. Gessler, J. P. Ferrio, R. Hommel, K. Treydte, R. A. Werner, R. K. Monson, Stable isotopes in tree rings: towards a mechanistic understanding of isotope fractionation and mixing processes from the leaves to the wood, Tree Physiology, 2014, 34, 8, 796

    CrossRef

  5. 5
    Dolores R. Piperno, Irene Holst, Klaus Winter, Owen McMillan, Teosinte before domestication: Experimental study of growth and phenotypic variability in Late Pleistocene and early Holocene environments, Quaternary International, 2014,

    CrossRef

  6. 6
    P. Gepts, Encyclopedia of Agriculture and Food Systems, 2014,

    CrossRef

  7. 7
    Yunpu Zheng, Ming Xu, Ruixing Hou, Ruichang Shen, Shuai Qiu, Zhu Ouyang, Effects of experimental warming on stomatal traits in leaves of maize (Zea may L.), Ecology and Evolution, 2013, 3, 9
  8. 8
    A. A. Temme, W. K. Cornwell, J. H. C. Cornelissen, R. Aerts, Meta-analysis reveals profound responses of plant traits to glacial CO2 levels, Ecology and Evolution, 2013, 3, 13
  9. 9
    R. F. Sage, Photorespiratory compensation: a driver for biological diversity, Plant Biology, 2013, 15, 4
  10. 10
    Carl P. Boardman, Vincent Gauci, Andrew Fox, Stephen Blake, David J. Beerling, Reduction of the temperature sensitivity of minerotrophic fen methane emissions by simulated glacial atmospheric carbon dioxide starvation, Journal of Geophysical Research: Biogeosciences, 2013, 118, 2
  11. 11
    Cory J. Lindgren, Karen L. Castro, Heather A. Coiner, Robert E. Nurse, Stephen J. Darbyshire, The Biology of Invasive Alien Plants in Canada. 12.Pueraria montanavar.lobata(Willd.) Sanjappa & Predeep, Canadian Journal of Plant Science, 2013, 93, 1, 71

    CrossRef

  12. 12
    Christopher Rico, Jarmila Pittermann, H. Wayne Polley, Michael J. Aspinwall, Phillip A. Fay, The effect of subambient to elevated atmospheric CO2 concentration on vascular function in Helianthus annuus: implications for plant response to climate change, New Phytologist, 2013, 199, 4
  13. 13
    J.P. Ferrio, G. Arab, R. Buxó, E. Guerrero, M. Molist, J. Voltas, J.L. Araus, Agricultural expansion and settlement economy in Tell Halula (Mid-Euphrates valley): A diachronic study from early Neolithic to present, Journal of Arid Environments, 2012, 86, 104

    CrossRef

  14. 14
    Patrick J. Vogan, Rowan F. Sage, Effects of low atmospheric CO2 and elevated temperature during growth on the gas exchange responses of C3, C3–C4 intermediate, and C4 species from three evolutionary lineages of C4 photosynthesis, Oecologia, 2012, 169, 2, 341

    CrossRef

  15. 15
    David T. Tissue, James D. Lewis, Learning from the past: how low [CO2] studies inform plant and ecosystem response to future climate change, New Phytologist, 2012, 194, 1
  16. 16
    Robert G. Elston, Dong Guanghui, Zhang Dongju, Late Pleistocene intensification technologies in Northern China, Quaternary International, 2011, 242, 2, 401

    CrossRef

  17. 17
    Jörn Germer, Joachim Sauerborn, Folkard Asch, Jan de Boer, Jürgen Schreiber, Gerd Weber, Joachim Müller, Skyfarming an ecological innovation to enhance global food security, Journal für Verbraucherschutz und Lebensmittelsicherheit, 2011, 6, 2, 237

    CrossRef

  18. 18
    T. Douglas Price, Ofer Bar-Yosef, The Origins of Agriculture: New Data, New Ideas, Current Anthropology, 2011, 52, S4, S163

    CrossRef

  19. You have free access to this content19
    Tao Sang, Toward the Domestication of Lignocellulosic Energy Crops: Learning from Food Crop Domestication, Journal of Integrative Plant Biology, 2011, 53, 2
  20. 20
    Dorian Q. Fuller, Yo-Ichiro Sato, Cristina Castillo, Ling Qin, Alison R. Weisskopf, Eleanor J. Kingwell-Banham, Jixiang Song, Sung-Mo Ahn, Jacob van Etten, Consilience of genetics and archaeobotany in the entangled history of rice, Archaeological and Anthropological Sciences, 2010, 2, 2, 115

    CrossRef

  21. 21
    BARNEY S. KGOPE, WILLIAM J. BOND, GUY F. MIDGLEY, Growth responses of African savanna trees implicate atmospheric [CO2] as a driver of past and current changes in savanna tree cover, Austral Ecology, 2010, 35, 4
  22. 22
    Daniel Zizumbo-Villarreal, Patricia Colunga-GarcíaMarín, Origin of agriculture and plant domestication in West Mesoamerica, Genetic Resources and Crop Evolution, 2010, 57, 6, 813

    CrossRef

  23. 23
    A.H. Laskar, N. Sharma, R. Ramesh, R.A. Jani, M.G. Yadava, Paleoclimate and paleovegetation of Lower Narmada Basin, Gujarat, Western India, inferred from stable carbon and oxygen isotopes, Quaternary International, 2010, 227, 2, 183

    CrossRef

  24. 24
    Laci M. Gerhart, Joy K. Ward, Plant responses to low [CO2] of the past, New Phytologist, 2010, 188, 3
  25. 25
    Christopher E. Doughty, The development of agriculture in the Americas: an ecological perspective, Ecosphere, 2010, 1, 6, art21

    CrossRef

  26. 26
    T. D. Price, Ancient farming in eastern North America, Proceedings of the National Academy of Sciences, 2009, 106, 16, 6427

    CrossRef

  27. 27
    Axel Kleidon, Climatic constraints on maximum levels of human metabolic activity and their relation to human evolution and global change, Climatic Change, 2009, 95, 3-4, 405

    CrossRef

  28. 28
    Malcolm Possell, C. Nicholas Hewitt, Gas exchange and photosynthetic performance of the tropical tree Acacia nigrescens when grown in different CO2 concentrations, Planta, 2009, 229, 4, 837

    CrossRef

  29. 29
    Christine E. Edwards, Monia S. H. Haselhorst, Autumn M. McKnite, Brent E. Ewers, David G. Williams, Cynthia Weinig, Genotypes of Brassica rapa respond differently to plant-induced variation in air CO2 concentration in growth chambers with standard and enhanced venting, Theoretical and Applied Genetics, 2009, 119, 6, 991

    CrossRef

  30. 30
    Miquel A Gonzàlez-Meler, Elena Blanc-Betes, Charles E Flower, Joy K Ward, Nuria Gomez-Casanovas, Plastic and adaptive responses of plant respiration to changes in atmospheric CO2 concentration, Physiologia Plantarum, 2009, 137, 4
  31. You have free access to this content31
    Joy K. Ward, David A. Myers, Richard B. Thomas, Physiological and Growth Responses of C3 and C4 Plants to Reduced Temperature When Grown at Low CO2 of the Last Ice Age, Journal of Integrative Plant Biology, 2008, 50, 11
  32. 32
    Valery J. Terwilliger, Zewdu Eshetu, Albert Colman, Tesfaye Bekele, Alemu Gezahgne, Marilyn L. Fogel, Reconstructing palaeoenvironment from δ13C and δ15N values of soil organic matter: A calibration from arid and wetter elevation transects in Ethiopia, Geoderma, 2008, 147, 3-4, 197

    CrossRef

  33. 33
    JENNIFER CUNNIFF, COLIN P. OSBORNE, BRAD S. RIPLEY, MICHAEL CHARLES, GLYNIS JONES, Response of wild C4 crop progenitors to subambient CO2 highlights a possible role in the origin of agriculture, Global Change Biology, 2008, 14, 3
  34. 34
    Lewis H. Ziska, Rising Atmospheric Carbon Dioxide and Plant Biology: The Overlooked Paradigm, DNA and Cell Biology, 2008, 27, 4, 165

    CrossRef

  35. 35
    L. H. Ziska, R. C. Sicher, K. George, J. E. Mohan, Rising Atmospheric Carbon Dioxide and Potential Impacts on the Growth and Toxicity of Poison Ivy (Toxicodendron Radicans), Weed Science, 2007, 55, 4, 288

    CrossRef

  36. 36
    Robert L. Bettinger, Loukas Barton, Peter J. Richerson, Robert Boyd, Hui Wang, Won Choi, Late Quaternary Climate Change and Human Adaptation in Arid China, 2007,

    CrossRef

  37. 37
    CATHERINE D. CAMPBELL, ROWAN F. SAGE, Interactions between the effects of atmospheric CO2 content and P nutrition on photosynthesis in white lupin (Lupinus albus L.), Plant, Cell & Environment, 2006, 29, 5
  38. 38
    Lewis Ziska, G Brett Runion, Agroecosystems in a Changing Climate, 2006,

    CrossRef

  39. 39
    L. H. Ziska, S. D. Emche, E. L. Johnson, K. George, D. R. Reed, R. C. Sicher, Alterations in the production and concentration of selected alkaloids as a function of rising atmospheric carbon dioxide and air temperature: implications for ethno-pharmacology, Global Change Biology, 2005, 11, 10
  40. 40
    Catherine D. Campbell, Rowan F. Sage, Ferit Kocacinar, Danielle A. Way, Estimation of the whole-plant CO2 compensation point of tobacco (Nicotiana tabacum L.), Global Change Biology, 2005, 11, 11
  41. 41
    Brian F. Byrd, Reassessing the Emergence of Village Life in the Near East, Journal of Archaeological Research, 2005, 13, 3, 231

    CrossRef

  42. 42
    Rowan F. Sage, The evolution of C4 photosynthesis, New Phytologist, 2004, 161, 2
  43. 43
    José Luis Araus, Gustavo Ariel Slafer, Ramón Buxó, Ignacio Romagosa, Productivity in prehistoric agriculture: physiological models for the quantification of cereal yields as an alternative to traditional approaches, Journal of Archaeological Science, 2003, 30, 6, 681

    CrossRef

  44. 44
    Lewis H. Ziska, The impact of nitrogen supply on the potential response of a noxious, invasive weed, Canada thistle (Cirsium arvense) to recent increases in atmospheric carbon dioxide, Physiologia Plantarum, 2003, 119, 1
  45. 45
    David R. Harris, Evolution on Planet Earth, 2003,

    CrossRef

  46. 46
    C. D. Campbell, R. F. Sage, Interactions between atmospheric CO2 concentration and phosphorus nutrition on the formation of proteoid roots in white lupin (Lupinus albus L.), Plant, Cell & Environment, 2002, 25, 8
  47. 47
    H. Maherali, C. D. Reid, H. W. Polley, H. B. Johnson, R. B. Jackson, Stomatal acclimation over a subambient to elevated CO2 gradient in a C3/C4 grassland, Plant, Cell & Environment, 2002, 25, 4
  48. 48
    Environmental Physiology of Plants, 2002,

    CrossRef

  49. 49
    Rowan F Sage, John R Coleman, Effects of low atmospheric CO2 on plants: more than a thing of the past, Trends in Plant Science, 2001, 6, 1, 18

    CrossRef

  50. 50
    R. F. Sage, Environmental and Evolutionary Preconditionsfor the Origin and Diversification of the C4 PhotosyntheticSyndrome, Plant Biology, 2001, 3, 3
  51. 51
    José Luis Araus, Gustavo Ariel Slafer, Ignacio Romagosa, Miquel Molist, FOCUS: Estimated Wheat Yields During the Emergence of Agriculture Based on the Carbon Isotope Discrimination of Grains: Evidence from a 10th Millennium BP Site on the Euphrates, Journal of Archaeological Science, 2001, 28, 4, 341

    CrossRef

  52. 52
    Laurel J. Anderson, Hafiz Maherali, Hyrum B. Johnson, H. Wayne Polley, Robert B. Jackson, Gas exchange and photosynthetic acclimation over subambient to elevated CO2 in a C3–C4 grassland, Global Change Biology, 2001, 7, 6
  53. 53
    Rowan F. Sage, Encyclopedia of Biodiversity, 2001,

    CrossRef

  54. 54
    J. M. Grünzweig, CH. Körner, Growth and reproductive responses to elevated CO2 in wild cereals of the northern Negev of Israel, Global Change Biology, 2000, 6, 6
  55. 55
    Zhijun Zhao, Dolores R. Piperno, Late Pleistocene/Holocene Environments in the middle Yangtze River Valley, China and rice (oryza sativa L.) domestication: The phytolith evidence, Geoarchaeology, 2000, 15, 2
  56. 56
    R.F. Sage, Redesigning Rice Photosynthesis to Increase Yield, Proceedings of the Workshop on the Quest to Reduce Hunger:Redesigning Rice Photosynthesis, 2000,

    CrossRef

  57. 57
    JoY. K. Ward, David T. Tissue, Richard B. Thomas, . And, BoyD. R. Strain, Comparative responses of model C3 and C4 plants to drought in low and elevated CO2, Global Change Biology, 1999, 5, 8
  58. 58
    Mark Pagani, Michael A. Arthur, Katherine H. Freeman, Miocene evolution of atmospheric carbon dioxide, Paleoceanography, 1999, 14, 3
  59. 59
    Sharon A. Cowling, Martin T. Sykes, Physiological Significance of Low Atmospheric CO2 for Plant–Climate Interactions, Quaternary Research, 1999, 52, 2, 237

    CrossRef

  60. 60
    Cowling Sharon A., Simulated effects of low atmospheric CO2 on structure and composition of North American vegetation at the Last Glacial Maximum, Global Ecology and Biogeography, 1999, 8, 2
  61. 61
    Rowan F. Sage, C4 Plant Biology, 1999,

    CrossRef

  62. 62
    Rowan F. Sage, Sharon A. Cowling, Carbon Dioxide and Environmental Stress, 1999,

    CrossRef

  63. 63
    Nikolaas J. van der Merwe, Hartmut Tschauner, C4 Plant Biology, 1999,

    CrossRef

  64. 64
    S. A. Cowling, R. F. Sage, Interactive effects of low atmospheric CO2 and elevated temperature on growth, photosynthesis and respiration in Phaseolus vulgaris, Plant, Cell & Environment, 1998, 21, 4
  65. 65
    Ofer Bar-Yosef, On the Nature of Transitions: the Middle to Upper Palaeolithic and the Neolithic Revolution, Cambridge Archaeological Journal, 1998, 8, 02, 141

    CrossRef

  66. 66
    The Origins of Agriculture in the Lowland Neotropics, 1998,

    CrossRef

  67. 67
    An Evaluation of the Impact of Rising Carbon Dioxide and Climatic Change on Weed Biology: From the Cell to the Plant,