Stable isotopes in archaeobotanical research
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- 作者:Girolamo Fiorentino (1)
Juan Pedro Ferrio (2)
Amy Bogaard (3)
Jos茅 Luis Araus (4)
Simone Riehl (5)
1. Laboratory of Archaeobotany and Palaeoecology ; University of Salento ; Lecce ; Italy
2. Department of Crop and Forest Science-AGROTECNIO Center ; University of Lleida ; Lleida ; Spain
3. School of Archaeology ; University of Oxford ; Oxford ; Great Britain
4. Department of Plant Biology ; University of Barcelona ; Barcelona ; Spain
5. Institute for Archaeological Science and Senckenberg Research Center for Human Evolution and Palaeoecology ; University of T眉bingen ; Tubingen ; Germany - 关键词:Stable isotopes ; Archaeobotany ; Seeds ; Charcoal
- 刊名:Vegetation History and Archaeobotany
- 出版年:2015
- 出版时间:January 2015
- 年:2015
- 卷:24
- 期:1
- 页码:215-227
- 全文大小:586 KB
- 参考文献:1. Aggarwal J, Habicht-Mauche J, Juarez C (2008) Application of heavy stable isotopes in forensic isotope geochemistry: a review. Appl Geochem 23:2,658鈥?,666
2. Aguilera M, Araus JL, Voltas J, Rodr铆guez-Ariza MO, Molina F, Rovina N, Bux贸 R, Ferrio JP (2008) Stable carbon and nitrogen isotopes and quality traits of fossil cereal grains provide clues on sustainability at the beginnings of Mediterranean agriculture. Rapid Commun Mass Spectrom 22:1,653鈥?,663
3. Aguilera M, Ferrio JP, P茅rez G, Araus JL, Voltas J (2012) Holocene changes in precipitation seasonality in the western Mediterranean Basin: a multi-species approach using 未13C of archaeobotanical remains. J Quat Sci 27:192鈥?02
4. Amundson R, Austin AT, Schuur AG, Yoo K, Matzek V, Kendall C, Uebesax A, Brenner D, Baisden WT (2003) Global patterns of the isotopic composition of soil and plant nitrogen. Global Biogeochem Cy 17:1031. doi:10.1029/2002GB001903
5. Araus JL, Bux贸 R (1993) Changes in carbon isotope discrimination in grain cereals from the north-western Mediterranean basin during the past seven millennia. Aust J Plant Physiol 20:117鈥?28
6. Araus JL, Febrero A, Bux贸 R, Camalich MD, Martin D, Molina F, Rodriguez-Ariza MO, Romagosa I (1997a) Changes in carbon isotope discrimination in grain cereals from different regions of the western Mediterranean basin during the past seven millennia. Palaeoenvironmental evidence of a differential change in aridity during the late Holocene. Glob Change Biol 3:107鈥?18
7. Araus JL, Febrero A, Bux贸 R, Rodriguez-Ariza MO, Molina F, Camalich MD, Martin D, Voltas J (1997b) Identification of ancient irrigation practices based on the carbon isotope discrimination of plant seeds: a case study from the South-East Iberian Peninsula. J Archaeol Sci 24:729鈥?40
8. Araus JL, Febrero A, Catala M, Molist M, Voltas J, Romagosa I (1999a) Crop water availability in early agriculture: evidence from carbon isotope discrimination of seeds from a tenth millennium BP site on the Euphrates. Glob Change Biol 5:201鈥?12
9. Araus JL, Slafer GA, Romagosa I (1999b) Durum wheat and barley yields in antiquity estimated from 13C discrimination of archaeological grains: a case study from the Western Mediterranean Basin. Aust J Plant Physiol 26:345鈥?52
10. Araus JL, Slafer GA, Reynolds MP, Royo C (2002) Plant breeding and drought in C3 cereals: What should we breed for? Ann Bot 89:925鈥?40
11. Araus JL, Slafer GA, Bux贸 R, Romagosa I (2003a) Productivity in prehistoric agriculture: physiological models for the quantification of cereal yields as an alternative to traditional approaches. J Archaeol Sci 30:681鈥?93
12. Araus JL, Villegas D, Aparicio N, Garc铆a-del-Moral LF, Elhani S, Rharrabti Y, Ferrio JP, Royo C (2003b) Environmental factors determining carbon isotope discrimination and yield in durum wheat under Mediterranean conditions. Crop Sci 43:170鈥?80
13. Araus JL, Ferrio JP, Bux贸 R, Voltas J (2007) The historical perspective of dryland agriculture: lessons learned from 10000聽years of wheat cultivation. J Exp Bot 58:131鈥?45
14. Araus JL, Cabrera-Bosquet L, Serret MD, Bort J, Nieto-Taladriz MT (2013) Comparative performance of 未13C, 未18O and 未15N for phenotyping durum wheat adaptation to a dryland environment. Funct Plant Biol 40:595鈥?08
15. Araus JL, Ferrio JP, Voltas J, Aguilera M, Bux贸 R (2014) Agronomic conditions and crop evolution in ancient Near East agriculture. Nat Commun 5. doi:10.1038/ncomms4953
16. Barbour MM (2007) Stable oxygen isotope composition of plant tissue: a review. Funct Plant Biol 34:83鈥?4
17. Bogaard A, Heaton THE, Poulton P, Merbach I (2007) The impact of manuring on nitrogen isotope ratios in cereals: archaeological implications for reconstruction. J Archaeol Sci 34:335鈥?43
18. Bogaard A, Fraser R, Heaton THE, Wallace M, Vaiglova P, Charles M, Jones G, Evershed RP, Styring AK, Andersen NH, Arbogast RM, Bartoseiwicz L, Gardeisen A, Kanstrup M, Maier U, Marinava E, Ninov L, Sch盲fer M, Stephan E (2013) Crop manuring and intensive land management by Europe鈥檚 first farmers. P Natl Acad Sci 110:12,589鈥?2,594
19. Bogaard A, Henton E, Evans JA, Twiss KC, Charles MP, Vaiglova P, Russell N (2014) Locating land use at Neolithic 脟atalh枚y眉k, Turkey: the implications of 87Sr/86Sr signatures in plants and sheep tooth sequences. Archaeometry 56:860鈥?77
20. Bol R, Eriksen J, Smith P, Garnett MH, Coleman K, Christensen BT (2005) The natural abundance of C-13, N-15, S-34 and C-14 in archived (1923鈥?000) plant and soil samples from the Askov long-term experiments on animal manure and mineral fertilizer. Rapid Commun Mass Spectrom 19:3,216鈥?,226
21. Braadbaart F (2008) Carbonisation and morphological changes in modern dehusked and husked / Triticum dicoccum and / Triticum aestivum grains. Veget Hist Archaeobot 17:155鈥?66
22. Braadbaart F, Van der Horst J, Boon JJ, Van Bergen PF (2004) Laboratory simulations of the transformation of emmer wheat as a result of heating. J Therm Anal Calorim 77:957鈥?73
23. Branch S, Burke S, Evans P, Fairman B, Wolff Briche CSL (2003) A preliminary study in determining the geographical origin of wheat using isotope ratio inductively coupled plasma mass spectrometry with 13C, 15N mass spectrometry. J Anal At Spectrom 18:17鈥?2
24. Buchmann N, Brooks JR, Rapp KD, Ehleringer JR (1996) Carbon isotope composition of C4 grasses is influenced by light and water supply. Plant Cell Environ 19:392鈥?02
25. Cabrera-Bosquet L, Molero G, Nogu茅s S, Araus JL (2009a) Water and nitrogen conditions affect the relationships of 螖13C and 螖18O with gas exchange and growth in durum wheat. J Exp Bot 60:1,633鈥?,644
26. Cabrera-Bosquet L, Sanchez C, Araus JL (2009b) Oxygen isotope enrichment (螖18O) reflects yield potential and drought resistance in maize. Plant Cell Environ 32:1,487鈥?,499
27. Cabrera-Bosquet L, S谩nchez C, Araus JL (2009c) How yield relates to ash content, 螖13C and 螖18O in maize grown under different water regimes. Ann Bot 104:1,207鈥?,216
28. Cabrera-Bosquet L, Albrizio R, Nogu茅s S, Araus JL (2011) Dual 螖13C/未18O response to water and nitrogen availability and its relationship with yield in field-grown durum wheat. Plant Cell Environ 34:418鈥?33
29. Calcagnile L, Quarta G, D鈥橢lia M (2005) High resolution accelerator-based mass spectrometry: precision accuracy and background. Appl Radiat Isot 62:623鈥?29
30. Caracuta V, Fiorentino G, Martinelli MC (2012) Plant remains and AMS: dating climate change in the Aeolian Islands (NorthEastern Sicily) during the 2nd millennium BC. Radiocarbon 54:689鈥?00
31. Chen S, Bai Y, Lin G, Han X (2005) Variations in life-form composition and foliar carbon isotope discrimination among eight plant communities under different soil moisture conditions in the Xilin river basin, Inner Mongolia, China. Ecol Res 20:167鈥?76
32. Chesson LA, Tipple BJ, Erkkila BR, Ehleringer JR (2013) Hydrogen and oxygen stable isotope analysis of pollen collected from honey. Grana 52:305鈥?15
33. Choi WJ, Ro HM, Hobbie EA (2003) Patterns of natural N-15 in soils and plants from chemically and organically fertilized uplands. Soil Biol Biochem 35:1,493鈥?,500
34. Condon AG, Richards RA, Farquhar GD (1987) Carbon isotope discrimination is positively correlated with grain yield and dry matter production in field-grown wheat. Crop Sci 27:996鈥?,001
35. Condon AG, Richards RA, Farquhar GD (1993) Relationships between carbon isotope discrimination, water use efficiency and transpiration efficiency for dryland wheat. Aust J Agric Res 44:1,693鈥?,711
36. Coubray S, Fiorentino G, Longobardi F, Zech-Matterne V, Casiello G (2013) New light on ancient foodstuff gathering at Cuma (south Italy) by stable isotopes in plant remains. In: Valamoti SM (ed) 16th Conference of the International Work Group for Palaeoethnobotany鈥揟hessaloniki. Greece, Abstract Book, p 121
37. DeNiro MJ, Hastorf CA (1985) Alteration of 15N/14N and 13C/12C ratios of plant matter during the initial stages of diagenesis: studies utilizing archaeological specimens from Peru. Geochim Cosmochim Acta 49:97鈥?15
38. Descolas-Gros C, Sch枚lzel C (2007) Stable isotope ratios of carbon and nitrogen in pollen grains in order to characterize plant functional groups and photosynthetic pathway types. New Phytol 176:390鈥?01
39. Drake BL, Hanson DT, Boone JL (2012) The use of radiocarbon-derived 螖13C as a paleoclimate indicator: applications in the Lower Alentejo of Portugal. J Archaeol Sci 39:2,888鈥?,896
40. Edwards TWD, Graf W, Trimborn P, Stichler W, Lipp J, Payer HD (2000) 螖13C response surface resolves humidity and temperature signals in trees. Geochim Cosmochim Acta 64:161鈥?67
41. Farquhar GD, Richards RA (1984) Isotopic composition of plant carbon correlates with water-use efficiency of wheat genotypes. Aust J Plant Physiol 11:539鈥?52
42. Farquhar GD, O鈥橪eary MH, Berry JA (1982) On the relationship between carbon isotope discrimination and the intercellular carbon dioxide concentration in leaves. Aust J Plant Physiol 9:121鈥?37
43. Farquhar GD, Cernusak LA, Barnes B (2007) Heavy water fractionation during transpiration. Plant Physiol 143:11鈥?8
44. Ferrio JP, Florit A, Vega A, Serrano L, Voltas J (2003) 螖13C and tree-ring width reflect different drought responses in / Quercus ilex and / Pinus halepensis. Oecologia 137:512鈥?18
45. Ferrio JP, Alonso N, Voltas J, Araus JL (2004) Estimating grain weight in archaeological cereal crops: a quantitative approach for comparison with current conditions. J Archaeol Sci 31:1,635鈥?,642
46. Ferrio JP, Araus JL, Bux贸 R, Voltas J, Bort J (2005) Water management practices and climate in ancient agriculture: inference from the stable isotope composition of archaeobotanical remains. Veget Hist Archaeobot 14:510鈥?17
47. Ferrio JP, Alonso N, L贸pez B, Araus JL, Voltas J (2006) Carbon isotope composition of fossil charcoal reveals aridity changes in NW Mediterranean Basin. Glob Change Biol 12:1鈥?4
48. Ferrio JP, Voltas J, Alonso N, Araus JL (2007) Reconstruction of climate and crop conditions in the past based on the carbon isotope signature of archaeobotanical remains. In: Dawson TE, Siegwolf R (eds) Isotopes as indicators of ecological change. Elsevier Academic Press, New York, pp 319鈥?32
49. Ferrio JP, Arab G, Bux贸 R, Guerrero E, Molist M, Voltas J, Araus JL (2012) Agricultural expansion and settlement economy in Tell Halula (Mid-Euphrates valley): a diachronic study from Early Neolithic to present. J Arid Environ 86:104鈥?12
50. Fiorentino G, Caracuta V, Calcagnile L, D鈥橢lia M, Matthiae P, Mavelli F, Quarta G (2008) Third millennium B.C. climate change in Syria highlighted by carbon stable isotope analysis of 14C-AMS dated plant remains from Ebla. Palaeogeogr Palaeoclimatol Palaeoecol 266:51鈥?8
51. Fiorentino G, Caracuta V, Volpe G, Turchiano M, Quarta G, D鈥橢lia M, Calcagnile L (2009) The First millennium AD climate fluctuations in the Tavoliere Plain (Apulia 鈥?Italy): new data from the 14C AMS-dated plant remains from the archaeological site of Faragola. Nucl Instrum Methods Phys Res Sect B 268:1,084鈥?,087
52. Fiorentino G, Caracuta V, Casiello G, Longobardi F, Sacco A (2012a) Studying ancient crop provenance: implications from 未13C and 未15N values of charred barley in a Middle Bronze Age silo at Ebla (NW Syria). Rapid Commun Mass Spectrom 26:327鈥?35
53. Fiorentino G, Caracuta V, Quarta G, Calcagnile L, Morandi Bonaccossi D (2012b) Palaeoprecipitation trends and cultural changes in Syrian protohistoric communites: the contribution of 未13C in ancient and modern vegetation. In: Kneisel J, Kirleis W, Dal Corso M, Taylor N, Tiedtke V (eds) Collapse or Continuity? Environment and development of bronze age human landscapes. Bonn: Habelt, pp 17鈥?4
54. Fischer RA, Rees D, Sayre KD, Lu ZM, Condon AG, Saavedra AL (1998) Wheat yield progress associated with higher stomatal conductance and photosynthetic rate, and cooler canopies. Crop Sci 38:1,467鈥?,475
55. Flohr P, M眉ldner G, Jenkins E (2011) Carbon stable isotope analysis of cereal remains as a way to reconstruct water availability: preliminary results. Water History 3:121鈥?44
56. Fraser RA, Bogaard A, Heaton T, Charles M, Jones G, Christensen BT, Halstead P, Merbach I, Poulton PR, Sparkes D (2011) Manuring and stable nitrogen isotope ratios in cereals and pulses: towards a new archaeobotanical approach to the inference of land use and dietary practices. J Archaeol Sci 38:2,790鈥?,804
57. Fraser R, Bogaard A, Charles M, Styring AK, Wallace M, Jones G, Ditchfield P, Heaton THEH (2013a) Assessing natural variation and the effects of charring, burial and pre-treatment on the stable carbon and nitrogen isotope values of archaeobotanical cereal and pulse remains. J Archaeol Sci 40:4,754鈥?,766
58. Fraser RA, Bogaard A, Sch盲fer M, Arbogast R-M, Heaton THEH (2013b) Integrating botanical, faunal and human stable carbon and nitrogen isotope values to reconstruct land use and palaeodiet at LBK Vaihingen an der Enz, Baden-W眉rttemberg. World Archaeol 45:492鈥?17
59. Guo G, Xie G (2006) The relationship between plant stable carbon isotope composition, precipitation and satellite data, Tibet Plateau, China. Quat Int 144:68鈥?1
60. Hall G, Woodborne S, Scholes M (2008) Stable carbon isotope ratios from archaeological charcoal as paleoenvironmental indicators. Chem Geol 247:384鈥?00
61. Handley LL, Raven JA (1992) The use of natural abundance of nitrogen isotopes in plant physiology and ecology. Plant Cell Environ 15:965鈥?85
62. Handley LL, Robinson D, Forster BP, Ellis RP, Scrimgeour CM, Gordon DC, Nero E, Raven JA (1997) Shoot 未15N correlates with genotype and salt stress in barley. Planta 201:100鈥?02
63. Hartman G, Danin A (2010) Isotopic values of plants in relation to water availability in the Eastern Mediterranean region. Oecologia 162:837鈥?52
64. Hastorf CA, DeNiro MJ (1985) Reconstruction of prehistoric plant production and cooking practices by a new isotopic method. Nature 315:489鈥?91
65. Hatt茅 C, Schwartz D (2003) Reconstruction of paleoclimates by isotopic analysis: What can the fossil isotopic record tell us about the plant life of past environments? Phytochem Rev 2:163鈥?77
66. Heaton THE, Jones G, Halstead P, Tsipropoulos T (2009) Variations in the 13C/12C ratios of modern wheat grain, and implications for interpreting data from Bronze Age Assiros Toumba, Greece. J Archaeol Sci 36:2,224鈥?,233
67. Hedges REM, Reynard LM (2007) Nitrogen isotopes and the trophic level of humans in archaeology. J Archaeol Sci 34:1,240鈥?,251
68. Hodson MJ, Parker AG, Leng MJ, Sloane HJ (2008) Silicon, oxygen and carbon isotope composition of wheat ( / Triticum aestivum L.) phytoliths: implications for palaeoecology and archaeology. J Quat Sci 23:331鈥?39
69. H枚gberg P (1997) Tansley review No. 95 15聽N natural abundance in soil-plant systems. New Phytol 137:179鈥?03
70. Jahren AH, Amundson RG, Kendall C, Wigand P (2001) Paleoclimatic reconstruction using the correlation in d18O of Hackberry carbonate and environmental water, North America. Quat Res 56:252鈥?63
71. Johnson DA, Asay KH, Read JJ, Ehleringer JR, Hall AE, Farquhar GD (1993) Genotypic and environmental variation for carbon isotope discrimination in crested wheatgrass, a perennial forage grass. In: Ehleringer JR, Hall AE, Farquhar GD (eds) Stable isotopes and plant carbon-water relations. Academic Press Inc., San Diego, pp 269鈥?80
72. Kelly S, Heaton K, Hoogewerff J (2005) Tracing the geographical origin of food: the application of multi-element and multi-isotope analysis. Trends Food Sci Techn 16:555鈥?67
73. Knudson KJ, Williams HM, Buikstra JE, Tomczak PD, Gordon GW, Anbar AD (2010) Introducing 未88/86Sr analysis in archaeology: a demonstration of the utility of strontium isotope fractionation in paleodietary studies. J Archaeol Sci 37:2,352鈥?,364
74. Korol RL, Kirschbaum MUF, Farquhar GD, Jeffreys M (1999) Effects of water status and soil fertility on the C-isotope signature in / Pinus radiata. Tree Physiol 19:551鈥?62
75. K眉hn M, Hadorn P (2004) Pflanzliche Makro- und Mikroreste aus Dung von Wiederk盲uern. In: Jacomet S, Leuzinger U, Schibler J (eds) Die jungsteinzeitliche Seeufersiedlung Arbon Bleiche 3: Umwelt und Wirtschaft. Amt f眉r Arch盲ologie des Kantons Thurgau, Frauenfeld, pp 327鈥?48
76. Lancelotti C, Caracuta V, Fiorentino G, Madella M, Ajithprasad P (2013) Holocene Monsoon Dynamics and Human Occupation in Gujarat: Stable Isotopes Analyses on Plant Remains. Heritage: J Multidiscip Stud Archaeol 1:288鈥?00
77. Lauer F, Prost K, Gerlach R, P盲tzold S, Wolf M, Urmersbach S, Amelung W (2014) Organic Fertilization and Sufficient Nutrient Status in Prehistoric Agriculture?鈥擨ndications from Multi-Proxy Analyses of Archaeological Topsoil Relicts. PLoS One 9:e106244
78. Lightfoot E, Stevens RE (2012) Stable isotope investigations of charred barley ( / Hordeum vulgare) and wheat ( / Triticum spelta) grains from Danebury Hillfort: implications for palaeodietary reconstructions. J Archaeol Sci 39:656鈥?62
79. Loader NJ, Hemming DL (2004) The stable isotope analysis of pollen as an indicator of terrestrial palaeoenvironmental change: a review of progress and recent developments. Quat Sci Rev 23:893鈥?00
80. Marino BD, DeNiro MJ (1987) Isotope analysis of archaeobotanicals to reconstruct past climates: effects of activities associated with food preparation on carbon, hydrogen and oxygen isotope ratios of plant cellulose. J Archaeol Sci 14:537鈥?48
81. Marino BD, MacElroy MB, Salawitch RJ, Spaulding WG (1992) Glacial-to-interglacial variations in the carbon isotopic composition of atmospheric CO2. Nature 357:461鈥?66
82. Masi A, Sadori L, Baneschi I, Siani AM, Zanchetta G (2013) Stable isotope analysis of archaeological oak charcoal from eastern Anatolia as a marker of mid-Holocene climate change. Plant Biol 15:83鈥?2
83. Miller JM, Williams RJ, Farquhar GD (2001) Carbon isotope discrimination by a sequence of Eucalyptus species along a subcontinental rainfall gradient in Australia. Funct Ecol 15:222鈥?32
84. Mu帽oz P, Voltas J, Araus JL, Igartua E, Romagosa I (1998) Changes over time in the adaptation of barley releases in north-eastern Spain. Plant Breeding 117:531鈥?35
85. Nelson DM, Hu FS, Mikucki JA, Tian J, Pearson A (2007) Carbon-isotopic analysis of individual pollen grains from C3 and C4 grasses using a spooling-wire microcombustion interface. Geochim Cosmochim Acta 71:4,005鈥?,014
86. Nelson DM, Hu FS, Scholes DR, Joshi N, Pearson A (2008) Using SPIRAL (Single Pollen Isotope Ratio AnaLysis) to estimate C3- and C4-grass abundance in the paleorecord. Earth Planet Sci Lett 269:11鈥?6
87. O鈥機onnell TC, Kneale CJ, Tasevska N, Kuhnle GGC (2012) The diet-body offset in human nitrogen isotopic values: a controlled dietary study. Am J Phys Anthropol 149:426鈥?34
88. Parker AG, Eckersley L, Smith MM, Goudie AS, Stokes S, Ward S, White K, Hodson MJ (2004) Holocene vegetation dynamics in the northeastern Rub鈥?al-Khali desert, Arabian Peninsula: a phytolith, pollen and carbon isotope study. J Quat Sci 19:665鈥?76
89. Passioura JB (2002) Environmental biology and crop improvement. Funct Plant Biol 29:537鈥?46
90. Poole I, Braadbaart F, Boon JJ, Van Bergen PF (2002) Stable carbon isotope changes during artificial charring of propagules. Org Geochem 33:1675鈥?681
91. Pustovoytov K, Riehl S, Hilger H (2010) Oxygen isotopic composition of fruit carbonate in Lithospermeae and its relevance to paleoclimate research in the Mediterranean. Global Planet Change 71:258鈥?68
92. Quarta G, D鈥橢lia M, Calcagnile L (2004) The influence of injection parameters on mass fractionation phenomena in radiocarbon analysis. Nucl Instrum Methods Phys Res, Sect B 217:644鈥?48
93. Rice SK, Giles L (1996) The influence of water content and leaf anatomy on carbon isotope discrimination and photosynthesis in / Sphagnum. Plant Cell Environ 19:118鈥?24
94. Riehl S (2008) Climate and agriculture in the ancient Near East: a synthesis of the archaeobotanical and stable carbon isotope evidence. Veget Hist Archaeobot 17:43鈥?1
95. Riehl S (2010a) Maintenance of agricultural stability in a changing environment鈥攖he archaeobotanical evidence at Emar. In: Finkbeiner U, Sakal F (eds) Emar after the closure of the Tabqa dam. The Syrian-German excavations 1996鈥?002. Vol 1: Late Roman and Medieval cemeteries and environmental studies. Subartu 25, Turnhout, pp 177鈥?24
96. Riehl S (2010b) Flourishing agriculture in times of political instability鈥攖he archaeobotanical and isotopic evidence from Tell Atchana. In: Yener KA (ed) Excavations in the plain of Antioch. Tell Atchana, Ancient Alalakh, a Bronze Age capital in the Amuq Valley, Turkey. The 2003鈥?004 excavation seasons. Ko莽 University Press, Istanbul, pp 123鈥?36. ISBN:聽9786055607135
97. Riehl S (2013) Inner-sample and inner-specific variability of 未13C in barley an its implications on the interpretation of drough stress in ancient near eastern agricultural societies. In: Valamoti SM (ed) 16th Conference of the International Work Group for Palaeoethnobotany鈥擳hessaloniki. Abstract Book, p 124. (http://iwgp-2013.web.auth.gr/images/Posters/riehl.pdf)
98. Riehl S, Bryson RA, Pustovoytov K (2008) Changing growing conditions for crops during the Near Eastern Bronze Age (3000-1200 BC): The stable carbon isotope evidence. J Archaeol Sci 35:1,011鈥?,022
99. Riehl S, Pustovoytov KE, Weippert H, Klett S, Hole F (2014) Drought stress variability in ancient Near Eastern agricultural systems evidenced by 未13C in barley grain. P Natl Acad Sci 111:12,348鈥?2,353
100. Roberts N, Eastwood WJ, Kuzucuo臒lu C, Fiorentino G, Caracuta V (2011) Climatic, vegetation and cultural change in the eastern Mediterranean during the mid-Holocene environmental transition. Holocene 21:147鈥?62
101. Sacco A, Brescia MA, Sgaramella A, Sacco D (2005) Characterization of the composition and the geographical origin of food products by means of nuclear magnetic resonance and isotope ratio mass spectrometry. Recent Res Dev Agri Food Chem 6:119鈥?42
102. Schoeninger M, DeNiro M, Tauber H (1983) Stable nitrogen isotope ratios of bone collagen reflect marine and terrestrial components of prehistoric human diet. Science 220:1,381鈥?,383
103. Sembayran M, Dixon L, Goulding KWT, Bol R (2008) Long-term influence of manure and mineral nitrogen applications on plant and soil 15N and 13C values from the Broadbalk Wheat Experiment. Rapid Commun Mass Spectrom 22:1,735鈥?,740
104. Shearer G, Kohl DH (1989) Estimates of N2 fixation in ecosystems: the need for and basis of the 15N natural abundance method. Ecol Stud 68:342鈥?74
105. Slafer GA, Araus JL, Royo C, Garc铆a-del-Moral LF (2005) Promising eco-physiological traits for genetic improvement of cereal yields in Mediterranean environments. Ann Appl Biol 146:61鈥?0
106. Stellati A, Fiorentino G, Longobardi F, Casiello G, Cassano R, Fioriello SC (2013) The application of stable isotopes analyses on cereal caryopses as a tool to discriminate the crop provenience at Late Antiquity harbour of Egnathia. In: Valamoti SM (ed) 16th Conference of the International Work Group for Palaeoethnobotany鈥揟hessaloniki. Greece, Abstract Book, p 125
107. Stewart GR, Turnbull MH, Schmidt S, Erskine PD (1995) 13C natural abundance in plant communities along a rainfall gradient: a biological integrator of water availability. Aust J Plant Physiol 22:51鈥?5
108. Styring A, Manning H, Fraser R, Wallace M, Jones G, Charles M, Heaton THE, Bogaard A, Evershed RP (2013) The effect of charring and burial on the biochemical composition of cereal grains: investigating the integrity of archaeological plant material. J Archaeol Sci 40:4,767鈥?,779
109. Tauber H (1981) 13C evidence for dietary habits of prehistoric man in Denmark. Nature 292:332鈥?33
110. Tieszen LL, Fagre T (1993) Carbon isotopic variability in modern and archaeological maize. J Archaeol Sci 20:25鈥?0
111. Toolin LJ, Eastoe CJ (1993) Late pleistocene recent atmospheric delta-C-13 record in C4 grasses. Radiocarbon 35:263鈥?69
112. Unkovich MJ, Pate JS (2000) An appraisal of recent field measurements of symbiotic N2 fixation by annual legumes. Field Crops Res 65:211鈥?28
113. Vaiglova P, Bogaard A, Collins M, Cavanagh W, Mee C, Renard J, Lamb A, Gardeisen A, Fraser R (2014) An integrated stable isotope study of plants and animals from Kouphovouno, southern Greece: a new look at Neolithic farming. J Archaeol Sci 42:201鈥?15
114. Vaiglova P, Snoeck C, Nitsch E, Bogaard A, Lee-Thorp J (in press) Impact of contamination and pre-treatment on stable carbon and nitrogen isotopic composition of charred plant remains. Rapid Commun Mass Spectrom
115. Van der Veen M, Jones G (2006) A re-analysis of agricultural production and consumption: implications for understanding the British Iron Age. Veget Hist Archaeobot 15:217鈥?28
116. Vernet JL, Pachiaudi C, Bazile F, Durand A, Fabre L, Heinz C, Solari ME, Thiebault S (1996) Le 未13C de charbons de bois pr茅historiques et historiques m茅diterran茅es, de 35000 BP a l鈥檃ctuel. Premiers r茅sultats. CR Acad sci Paris, T. 323, serie IIa: 319鈥?24
117. Voltas I, Ferrio JP, Alonso N, Araus JL (2008) Stable carbon isotopes in archaeobotanical remains and palaeoclimate. Contrib Sci 4:21鈥?1
118. Wallace M, Jones G, Charles M, Fraser R, Halstead P, Heaton THE, Bogaard A (2013) Stable carbon isotope analysis as a direct means of inferring crop water status and water management practices. World Archaeol 45:388鈥?09
119. Warren CR, McGrath JF, Adams MA (2001) Water availability and carbon isotope discrimination in conifers. Oecologia 127:426鈥?86
120. Watzka M, Buchgraber K, Wanek W (2006) Natural 15N abundance of plants and soils under different management practices in a montane grassland. Soil Biol Biochem 38:1,564鈥?,576
121. Weiguo L, Xiahong F, Youfeng N, Qingle Z, Yunning C, Zhisheng A (2005) 未13C variation of C3 and C4 plants across an Asian monsoon gradient in arid northwestern China. Glob Change Biol 11:1,094鈥?,100
122. White JWC, Ciais P, Figge RA, Kenny R, Markgraf V (1994) A high resolution record of atmospheric CO2 content from carbon isotopes in peat. Nature 367:153鈥?56
123. Williams DG, Gempko V, Fravolini A, Leavitt SW, Wall GW, Kimball BA, Pinter PJ Jr, LaMorte R, Ottman M (2001) Carbon isotope discrimination by / Sorghum bicolor under CO2 enrichment and drought. New Phytol 150:285鈥?93
124. Williams DG, Coltrain JB, Lott M, English NB, Ehleringer JR (2005) Oxygen isotopes in cellulose identify source water for archaeological maize in the American Southwest. J Archaeol Sci 32:931鈥?39
125. Yang Q, Li X, Liu W, Zhou X, Zhao K, Sun N (2011) Carbon isotope fractionation during low temperature carbonization of foxtail and common millets. Org Geochem 42:713鈥?19
126. Yousfi S, Serret MD, Araus JL (2009) Shoot 未15N gives a better reflection than ion concentration or 螖13C of genotypic differences in the response of durum wheat to salinity. Funct Plant Biol 36:1鈥?2
127. Zhao FJ, Spiro B, McGrath SP (2001) Trends in 13C/12C ratios and C isotope discrimination of wheat since 1845. Oecologia 128:336鈥?42 - 刊物类别:Earth and Environmental Science
- 刊物主题:Earth sciences
Geology
Anthropology - 出版者:Springer Berlin / Heidelberg
- ISSN:1617-6278
文摘
In recent decades the analysis of stable isotopes in plants has become a useful method to infer natural and anthropogenic effects on the growing conditions of plants. Here we present a review of the state-of-the-art regarding the use of stable isotopes in plant macroremains. After providing a brief theoretical and methodological background, we will concentrate on the most common applications developed so far: reconstruction of climate and crop growing conditions, and crop provenancing. Finally, we will discuss current methodological challenges, and potential new directions for research.