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Jungle

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  13. Fuller, D. Q. 2006. Agricultural origins and frontiers in South Asia: A working synthesis. Journal of World Prehistory 20: 1–86; Asouti, E., Fuller, D. Q. 2008. Trees and woodlands of South India: Archaeological Perspectives. Walnut Creek: Left Coast Press; Fuller, D. Q., Boivin, N., Hoogervorst, T., Allaby, R. 2011. Across the Indian Ocean: The prehistoric movement of plants and animals. Antiquity 85: 544–558; Morrison, K. 2002. Historicizing adaptation, adapting to history: Forager-traders in South and Southeast Asia. In K. Morrison, L. Junker (eds.). Forager-Traders in South and Southeast Asia. Cambridge: Cambridge University Press. Pp. 1–20.

  14. Yang, Y. D., Liu, L., Chen, X., Speller, C. F. 2008. Wild or domesticated: DNA analysis of ancient water buffalo remains from North China. Journal of Archaeological Science 35: 2778–2785; Wang, M-S., et al. 2020. 863 genomes reveal the origin and domestication of chicken. Cell Research 30: 693–701. doi: 10.1038/s41422-020-0349-y..

  15. Heckenberger, M., Neves, E. G. 2009. Amazonian archaeology. Annual Review of Anthropology 38: 251–266; Barton, H., Denham, T. 2011. Vegeculture and social life in Island Southeast Asia. In G. Barker, M. Janowski (eds.). Why Cultivate? Anthropological and Archaeological Approaches to Foraging-Farming Transitions in Southeast Asia. Cambridge: McDonald Institute Monographs. Pp. 17–25.

  16. Molina, J., et al. 2011. Molecular evidence for a single evolutionary origin of domesticated rice. Proceedings of the National Academy of Sciences of the United States of America 108: 8351–8356; Gutaker, R. M., et al. 2020. Genomic history and ecology of the geographic spread of rice. Nature Plants 6: 492–502; Fuller, D. Q., Qin, L. 2009. Water management and labour in the origins and dispersal of Asian rice. World Archaeology 41: 88–111.

  17. Weber, S., Lehman, H., Barela, T., Hawks, S., Harriman, D. 2010. Rice or millets: Early farming strategies in prehistoric central Thailand. Archaeological and Anthropological Sciences 2: 79–88; Deng, Z., et al. 2020. Validating earliest rice farming in the Indonesian archipelago. Scientific Reports 10. doi: 10.1038/s41598-020-67747-3; Barron, A., et al. 2020. Sherds as archaeological assemblages: Gua Sireh reconsidered. Antiquity 94: 1325–1336; Bellwood, P. 1993 Cultural and biological differentiation in peninsular Malaysia: The last 10,000 years. Asian Perspectives 32: 37–60; Krigbaum, J. 2003. Neolithic subsistence patterns in northern Borneo reconstructed with stable carbon isotopes of enamel. Journal of Anthropological Archaeology 22: 292–304.

  18. Neumann, K., et al. 2011. First farmers in the Central African rainforest: A view from southern Cameroon. Quaternary International 249: 53–62; Garcin, Y., et al. 2018. Early anthropogenic impact on western Central African rainforests 2,600 y ago. Proceedings of the National Academy of Sciences of the United States of America 115: 3261–3266.

  19. Wotzka, H. P. 2019. Ecology and culture of millets in African rainforests: Ancient, historical, and present-day evidence. In B. Eichhorn, A. Höhn (eds.). Trees, Grasses and Crops: People and Plants in Sub-Saharan Africa and Beyond. Bonn: Dr. Rudolf Habelt GmbH. Pp. 407–429; Hamilton, A. C., Karamura, D., Kakudidi, E. 2016. History and conservation of wild and cultivated plant diversity in Uganda: Forest species and banana varieties as case studies. Plant Diversity 38(1): 23–44; Bleasdale, M., et al. 2020. Isotopic and microbotanical insights into Iron Age agricultural reliance in the Central African rainforest. Communications Biology 3. doi: 10.1038/s42003-020-01324-2.

  CHAPTER 8: ISLAND PARADISES LOST?

  1. Russell, J. C., Kueffer, C. 2019. Island biodiversity in the Anthropocene. Annual Review of Environment and Resources 44: 31–60; Blackburn, T. M., Cassey, P., Duncan, R. P., Evans, K. L., Gaston, K. J. 2004. Alien extinction and mammalian introductions on oceanic islands. Science 305: 1955–1958.

  2. Turvey, S. T., Cheke, A. S. 2008. Dead as a dodo: The fortuitous rise to fame of an extinction icon. Historical Biology 20: 149–163; Martin P. S., Steadman D. W. 1999. Prehistoric extinctions on islands and continents. In R. D. E. MacPhee (ed.). Extinctions in Near Time. Advances in Vertebrate Paleobiology 2. Boston: Springer; Grayson, D. K. 2001. The archaeological record of human impacts on animal populations. Journal of World Prehistory 15: 1–68; Diamond, J. 2005. Collapse: How Societies Choose to Fail or Survive. London: Penguin Books; Fordham, D. A., Brook, B. W. 2010. Why tropical island endemics are acutely susceptible to global change. Biodiversity and Conservation 19: 329–342.

  3. Huebert, J. M., Allen, M. 2020. Anthropogenic forests, arboriculture, and niche construction in the Marquesas Islands (Polynesia). Journal of Anthropological Archaeology 57. doi: 10.1016/j.jaa.2019.101122; Kirch, P. V. 1982. Transported landscapes. Natural History 91: 32–35.

  4. Forster, J., Lake, I. R., Watkinson, A. R., Gill, J. A. 2011. Marine biodiversity in the Caribbean UK overseas territories: Perceived threats and constraints to environmental management. Marine Policy 35: 647–657.

  5. Napolitano, M. F., et al. 2019. Reevaluating human colonization of the Caribbean using chronometric hygiene and Bayesian modeling. Science Advances 5, no. 12. doi: 10.1126/sciadv.aar7806; Siegel, P. E., et al. 2015. Paleoenvironmental evidence for first human colonization of the eastern Caribbean. Quaternary Science Reviews 129: 275–295; Pagán-Jiménez, J. R., Rodríguez-Ramos, R., Reid, B. A., van den Bel, M., Hofman, C. L. 2015. Early dispersals of maize and other food plants into the southern Caribbean and northeastern South America. Quaternary Science Reviews 123: 231–246.

  6. Steadman, D. W., et al. 2005. Asynchronous extinction of Late Quaternary sloths on continents and islands. Proceedings of the National Academy of Sciences of the United States of America 102: 11763–11768; Cooke, S. B., Dávalos, L. M., Mychajliw, A. M., Turvey, S. T., Upham, N. S. 2016. Anthropogenic extinction dominates Holocene declines of West Indian mammals. Annual Review of Ecology, Evolution, and Systematics 48: 301–327; Rivera-Collazo, I. C. 2015. Por el camino verde: Long-term tropical socioecosystem dynamics and the Anthropocene as seen from Puerto Rico. Holocene 25:1604–1611.

  7. Fitzpatrick, S. M. 2015. The pre-Columbian Caribbean: Colonization, population dispersal, and island adaptations. PaleoAmerica 1(4): 305–331; Keegan, W. F. 2006. Archaic influences in the origins and development of Taíno societies. Caribbean Journal of Science 42: 1–10; Giovas, C. M., LeFebvre, M. J., Fitzpatrick, S. M. 2012. New records for prehistoric introduction of Neotropical mammals to the West Indies: Evidence from Carriacou, Lesser Antilles. Journal of Biogeography 39: 476–487; Fitzpatrick, S. M., Keegan, W. F. 2007. Human impacts and adaptations in the Caribbean islands: An historical ecology approach. Earth and Environmental Science Transactions of the Royal Society of Edinburgh 98: 29–45; Cooke, S. B., Dávalos, L. M., Mychajliw, A. M., Turvey, S. T., Upham, N. S. 2016. Anthropogenic extinction dominates Holocene declines of West Indian mammals. Annual Review of Ecology, Evolution, and Systematics 48: 301–327.

  8. Newsom, L. A., Wing, E. S. 2004. On Land and Sea: Native American Uses of Biological Resources in the West Indies. Tuscaloosa: University of Alabama Press; Turvey, S. T., Weksler, M., Morris, E. L., Nokkert, M. 2010. Taxonomy, phylogeny, and diversity of the extinct Lesser Antillean rice rats (Sigmodontinae: Oryzomyini), with description of a new genus and species. Zoological Journal of the Linnaean Society 160: 748–772; Giovas, C. M., Clark, M., Fitzpatrick, S. M., Stone, J. 2013. Intensifying collection and size increase of the tessellated nerite snail (Nerita tessellata) at the Coconut Walk site, Nevis, northern Lesser Antilles, AD 890–1440. Journal of Archaeological Science 40: 4024–4038.

  9. Bellwood, P. 2005. First Farmers. Oxford: Blackwell; Posth, C., et al. 2018. Language continuity despite population replacement in Remote Oceania. Nature Ecology & Evolution 2: 731–740; Kirch, P. V. 2017. On the Road of the Winds: An Archaeological History of the Pacific Islands Before European Contact. Berkeley: University of California Press; Montenegro, Á., Callaghan, R. T., Fitzpatrick, S. M. 2016. Using seafaring simulations and shortest-hop trajectories to model the prehistoric colonization of Remote Oceania. Proceedings of the National Academy of Sciences of the United States of America 113: 12685–1
2690.

  10. Larson, G., et al. 2007. Phylogeny and ancient DNA of Sus provides insights into Neolithic expansion in Island Southeast Asia and Oceania. Proceedings of the National Academy of Sciences of the United States of America 104: 4834–4839; Nogueira-Filho, S. L. G., Nogueira, S. S. C., Fragoso, J. M. V. 2009. Ecological impacts of feral pigs in the Hawaiian Islands. Biodiversity and Conservation 18. doi: 10.1007/s10531-009-9680-9; Kirch, P. V. 2001. Pigs, humans, and tropic competition on small Oceania islands. In A. Anderson, T. Murray (eds.). Australian Archaeologist: Collected Papers in Honour of Jim Allen. Canberra: Australian National University Press. Pp. 427–439; Kirch, P. V. 1982. Transported landscapes. Natural History 91: 32–35; Kinaston, R. L., Bedford, S. B., Spriggs, M., Anson, D., Buckley, H. 2016. Is there a “Lapita diet”? A comparison of Lapita and post-Lapita skeletal samples from four Pacific Island archaeological sites. In M. Oxenham, H. Buckley (eds.). The Routledge Handbook of Bioarchaeology in Southeast Asia and the Pacific Islands. London: Routledge. Pp. 427–461; Fall, P. L. 2010. Pollen evidence for plant introductions in a Polynesian tropical island ecosystem, Kingdom of Tonga. In S. G. Haberle, J. Stevenson, M. Prebble (eds.). Altered Ecologies: Fire, Climate and Human Influence on Terrestrial Landscapes. Canberra: Australian National University Press. Pp. 253–271; Morrison, A. E., Hunt, T. L. 2007. Human impacts on the nearshore environment: An archaeological case study from Kaua’i, Hawaiian Islands. Pacific Science 61: 325–345.

  11. Steadman, D. W. 2006. Extinction and Biogeography of Tropical Pacific Birds. Chicago: University of Chicago Press; Hunt, T. L. 2007. Rethinking Easter Island’s ecological catastrophe. Journal of Archaeological Science 34: 485–502.

  12. Tromp, M., et al. 2020. Exploitation and utilization of tropical rainforests indicated in dental calculus of ancient Oceanic Lapita culture colonists. Nature Human Behaviour 4: 489–495. doi: 10.1038/s41562-019-0808-y; Maxwell, J. J., Howarth, J. D., Vandergoes, M. J., Jacobsen, G. E., Barber, I. G. 2016. The timing and importance of arboriculture and agroforestry in a temperate East Polynesia Society, the Moriori, Rekohu (Chatham Island). Quaternary Science Reviews 149: 306–325; Lambrides, A. B. J., Weisler, M. I. 2016. Pacific Islands ichthyoarchaeology: Implications for the development of prehistoric fishing studies and global sustainability. Journal of Archaeological Research 24: 275–324.

  13. Giovas, C. 2006. No pig atoll: Island biogeography and the extirpation of a Polynesian domesticate. Asian Perspectives 45: 69–95; Matisoo-Smith, E. 2007. Animal translocations, genetic variation, and the human settlement of the Pacific. In J. S. Friedlaender (ed.). Genes, Language, and Culture History in the Southwest Pacific. Oxford: Oxford University Press. Pp. 157–170; Ladefoged, T. N., et al. 2011. Agricultural potential and actualized development in Hawai’i: An airborne LiDAR survey of the leeward Kohala field system (Hawai’i Island). Journal of Archaeological Science 38: 3605–3619; Kirch, P. V. 2010. How Chiefs Became Kings: Divine Kingship and the Rise of Archaic States in Ancient Hawai’i. Berkeley: University of California Press.

  14. Kirch, P., Yen, D. 1982. Tikopia: Prehistory and Ecology of a Polynesian Outlier. Bulletin 238. Honolulu: Bernice P. Bishop Museum; Ladefoged, T. N., et al. 2010. Soil nutrient analysis of Rapa Nui gardening. Archaeology in Oceania 45: 80–85; Rainbird, P. 2002. A message for our future? The Rapa Nui (Easter Island) ecodisaster and Pacific Island environments. World Archaeology 33: 436–451.

  15. Douglass, K., Zinke, J. 2015. Forging ahead by land and by sea: Archaeology and paleoclimate reconstruction in Madagascar. African Archaeological Review 32: 267–299; Hansford, J., et al. 2018. Early Holocene human presence in Madagascar evidenced by exploitation of avian megafauna. Science Advances 4: eaat6925. doi: 10.1126/sciadv.aat6925; Anderson, A., et al. 2018. New evidence of megafaunal bone damage indicates late colonization of Madagascar. PLOS ONE 13: e0204368. doi: 10.1371/journal.pone.0204368; Douglass, K., et al. 2019. A critical review of radiocarbon dates clarifies the human settlement of Madagascar. Quaternary Science Reviews 221: 105878; Burney, D. A., et al. 2004. A chronology for late prehistoric Madagascar. Journal of Human Evolution 47: 25–63; Crowley, B. E. 2010. A refined chronology of prehistoric Madagascar and the demise of the megafauna. Quaternary Science Reviews 29: 2591–2603; Martin, P. S. 1984. Prehistoric overkill: The global model. In P. S. Martin, R. G. Klein (eds.). Quaternary Extinctions: A Prehistoric Revolution. Tucson: University of Arizona Press. Pp. 354–403.

  16. Godfrey, L. R., et al. 2019. A new interpretation of Madagascar’s megafaunal decline: The “Subsistence Shift Hypothesis.” Journal of Human Evolution 130: 126–140; Douglass, K., et al. 2018. Multi-analytical approach to zooarchaeological assemblages elucidates Late Holocene coastal lifeways in southwest Madagascar. Quaternary International 471: 111–131; Burney, D. A., et al. 2004. A chronology for late prehistoric Madagascar. Journal of Human Evolution 47: 25–63; Crowley, B. E. 2010. A refined chronology of prehistoric Madagascar and the demise of the megafauna. Quaternary Science Reviews 29: 2591–2603; Li, H., et al. 2020. A multimillennial climatic context for the megafaunal extinctions in Madagascar and Mascarene Islands. Science Advances 6: eabb2459. doi: 10.1126/sciadv.abb2459.

  17. Godfrey, L. R., et al. 2019. A new interpretation of Madagascar’s megafaunal decline: The “Subsistence Shift Hypothesis.” Journal of Human Evolution 130: 126–140; Crowther, A., et al. 2016. Ancient crops provide first archaeological signature of the westward Austronesian expansion. Proceedings of the National Academy of Sciences of the United States of America 113: 6635–6640; Radimilahy, C. M., Crossland, Z. 2015. Situating Madagascar: Indian Ocean dynamics and archaeological histories. Azania: Archaeological Research in Africa 50: 495–518; Dewar, R. E., Richard, A. F. 2012. Madagascar: A history of arrivals, what happened, and will happen next. Annual Review of Anthropology 41: 495–517.

  18. Crowther, A., et al. 2016. Ancient crops provide first archaeological signature of the westward Austronesian expansion. Proceedings of the National Academy of Sciences of the United States of America 113: 6635–6640; Schwitzer, C., et al. 2014. Averting lemur extinctions amid Madagascar’s political crisis. Science 343: 842–843; Kaufmann, J. C. 2004. Prickly pear cactus and pastoralism in southwest Madagascar. Ethnology 43: 345–361.

  19. Galván, B., et al. 1999. Poblamiento prehistórico en la costa de Buena Vista del Norte (Tenerife). El conjunto arqueológico Fuente-Arena. Investigaciones Arqueológicas en Canarias 6: 9–257; Morales, J., Rodríguez, A., Alberto, V., Machado, C., Criado, C. 2009. The impact of human activities on the natural environment of the Canary Islands (Spain) during the pre-Hispanic stage (3rd-2nd century BC to 15th century AD): An overview. Environmental Archaeology 14: 27–36; Rando, J. C., Perera, M. A. 1994. Primeros datos de ornitofagia entre los aborígenes de Fuerteventura (Islas Canarias). Archeofauna 3: 13–19.

  20. Nogué, S., et al. 2013. The ancient forests of La Gomera, Canary Islands, and their sensitivity to environmental change. Journal of Ecology 101: 368–377; Machado, C. 1995. Approche paléoécologique et ethnobotanique du site archéologique “El Tendal” (N-E de l’Ile de La Palma, Archipel des Canaries). In CTHS (eds.). L’Homme préhistorique et la mer. 120 Congrés. Aix-en-Provence: CTHS. Pp. 179–186; Gangoso, L., Donázar, J. A., Scholz, S., Palacios, C. J., Hiraldo, F. 2006. Contradiction in conservation of island ecosystems: Plants, introduced herbivores and avian scavengers in the Canary Islands. Biodiversity and Conservation 15. doi: 10.1007/s10531-004-7181-4; Crosby, A. W. 1984. An ecohistory of the Canary Islands: A precursor of European colonization in the New World and Australasia 8: 214–235.

  21. Boivin, N. L., et al. 2016. Ecological consequences of human niche construction: Examining long-term anthropogenic shaping of global species distributions. Proceedings of the National Academy of Sciences of the United States of America 113: 6388–6396.

  CHAPTER 9: CITIES IN THE “JUNGLE”

  1. Diamond, J. 2005. Collapse: How Societies Choose to Fail or Survive. London: Penguin Books.

  2. Meggers, B. J. 1971. Amazonia: Man and Culture
in a Counterfeit Paradise. Wheeling: Harlan Davidson; Webster, D. 2002. The Fall of the Ancient Maya. London: Thames & Hudson; Bacus, E. A., Lucero, L. J. (eds.). 1999. Complex Polities in the Ancient Tropical World. Archaeological Papers of the American Anthropological Association (AAA) 9. Arlington: AAA; Algaze, G. 2018. Entropic cities: The paradox of urbanism in ancient Mesopotamia. Current Anthropology 59: 23–54; Wengrow, D. 2006. The Archaeology of Early Egypt: Social Transformations in North-East Africa, c. 10,000 to 2,650 BC. Cambridge: Cambridge University Press; Flad, R. 2018. Urbanism as technology in early China. Archaeological Research in Asia 14: 121–134.

  3. Childe, V. G. 1950. The Urban Revolution. Town Planning Review 21: 3–17; Postgate, J. N. 1992. Early Mesopotamia: Society and Economy at the Dawn of History. London: Routledge; Webster, D. 2002. The Fall of the Ancient Maya. London: Thames & Hudson.

  4. Martin, S., Grube, N. 2008. Chronicle of the Maya Kings and Queens: Deciphering the Dynasties of the Ancient Maya. London: Thames & Hudson; Greenwich Park climate station. Met Office. 2020. www.metoffice.gov.uk/research/climate/maps-and-data/uk-climate-averages/u10hb54gm; Scarborough, V. L. 1993. Water management in the southern Maya lowlands: An accretive model for the engineered landscape. Research in Economic Anthropology 7: 17–69; Beach, T., Dunning, N., Luzzadder-Beach, S., Cook, D. E., Lohse, J. 2006. Impacts of the ancient Maya on soils and soil erosion in the central Maya lowlands. Caterna 65: 166–178; Webster, D. 2002. The Fall of the Ancient Maya. London: Thames & Hudson.

  5. Fletcher, R. 2012. Low-density, agrarian-based urbanism: Scale, power and ecology. In M. E. Smith (ed.). The Comparative Archaeology of Complex Societies. Cambridge: Cambridge University Press. Pp. 285–320.

  6. Webster, D., et al. 2007. The Great Tikal Earthwork revisited. Journal of Field Archaeology 32: 41–64; Chase, A. F., et al. 2011. Airborne LiDAR, archaeology, and the ancient Maya landscape at Caracol, Belize. Journal of Archaeological Science 38: 387–398.

 

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