The Organization of Dissonance in Adena-Hopewell Societies of Eastern North America

Social complexity increased dramatically during the Middle Woodland period (ca. 200 BC-AD 500) in Eastern North America. Adena-Hopewell societies during this period built massive burial mounds, constructed complex geometric earthen enclosures, and maintained extensive trade networks in exotic craft goods. These material signatures suggest that coalition and consensus were sustained through social bonds since clear evidence for top-down leadership does not exist in Adena-Hopewell archaeology. Here, a framework grounded in new understandings of heterarchy is used to explore how coalitions were formed, organised, maintained, and/or shifted as a means to coordinate labour and ritual among Middle Woodland Period groups. Through re- analysis of the Wright Mound in Kentucky, and its burial contents, new insights into heterarchical organisation are used to achieve a wider, diachronic understanding of how humans in the past reached, realised, and rearranged forms of consensus and coalition

The Organization of Dissonance in Adena-Hopewell Societies of Eastern North America

Social complexity increased dramatically during the Middle Woodland period (ca. 200 BC-AD 500) in Eastern North America. Adena-Hopewell societies during this period built massive burial mounds, constructed complex geometric earthen enclosures, and maintained extensive trade networks in exotic craft goods. These material signatures suggest that coalition and consensus were sustained through social bonds since clear evidence for top-down leadership does not exist in Adena-Hopewell archaeology. Here, a framework grounded in new understandings of heterarchy is used to explore how coalitions were formed, organised, maintained, and/or shifted as a means to coordinate labour and ritual among Middle Woodland Period groups. Through re- analysis of the Wright Mound in Kentucky, and its burial contents, new insights into heterarchical organisation are used to achieve a wider, diachronic understanding of how humans in the past reached, realised, and rearranged forms of consensus and coalition

The Mississippian Transition at the Washausen Site: Demography and Community at a Tenth-Eleventh Century A.D. Mound Town in the American Bottom, Illinois.

This dissertation examines the development of the Washausen mound and village settlement in west-central Illinois, which was occupied during the tenth and eleventh centuries A.D. Results from a high-resolution geophysical survey as well as from excavations, artifact analyses, and radiocarbon dating provide information on how large farming villages were organized just prior to initial rapid growth of the massive Mississippian center of Cahokia. Casey Barrier presents a regional demographic trajectory demonstrating that large villages like Washausen formed through an ongoing process of population aggregations and dispersals by migrating residential groups. By taking a community-based approach informed by political-economic theories on kin-based agricultural societies, Barrier shows how coalesced corporate groups created new institutions that favored the development of larger nucleated settlements and regional integration.PhDAnthropologyUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/107276/1/cbarrier_1.pd

Prospecting for new questions: integrating geophysics to define anthropological research objectives and inform excavation strategies at monumental sites

Geophysical data have the potential to significantly contribute to archaeological research projects when effectively integrated with more traditional methods. Although pre-existing archaeological questions about a site may be answered using geophysical methods, beginning an investigation with an extensive geophysical survey can assist in understanding the function and archaeological potential of a site, and may even transform preconceptions about the type and spatial organisation of features that are present. In this way, these prospection tools not only accurately locate and map features to allow recovery of cultural material for identification and dating, we argue that they can go much further, allowing us to prospect for new and appropriate archaeological and anthropological research questions. Such an approach is best realised when geophysical and traditional archaeologists work together to define new objectives and strategies to address them, and by maintaining this collaboration to allow continual feedback between geophysical and archaeological data. A flexible research design is therefore essential in order to allow the methodologies to adapt to the site, the results, and the questions being posed. This methodology is demonstrated through two case studies from mound sites in southeast USA: the transitional Mississippian Washausen site in Illinois; and the Middle Woodland Garden Creek site in North Carolina. In both cases, integrating geophysical methods throughout the archaeological investigations has resulted in multiple phases of generating and addressing new research objectives. Although clearly beneficial at these two mound sites in southeast USA, this interdisciplinary approach has obvious implications well beyond these temporal and geographical areas

Prospecting for new questions: integrating geophysics to define anthropological research objectives and inform excavation strategies at monumental sites

Geophysical data have the potential to significantly contribute to archaeological research projects when effectively integrated with more traditional methods. Although pre-existing archaeological questions about a site may be answered using geophysical methods, beginning an investigation with an extensive geophysical survey can assist in understanding the function and archaeological potential of a site, and may even transform preconceptions about the type and spatial organisation of features that are present. In this way, these prospection tools not only accurately locate and map features to allow recovery of cultural material for identification and dating, we argue that they can go much further, allowing us to prospect for new and appropriate archaeological and anthropological research questions. Such an approach is best realised when geophysical and traditional archaeologists work together to define new objectives and strategies to address them, and by maintaining this collaboration to allow continual feedback between geophysical and archaeological data. A flexible research design is therefore essential in order to allow the methodologies to adapt to the site, the results, and the questions being posed. This methodology is demonstrated through two case studies from mound sites in southeast USA: the transitional Mississippian Washausen site in Illinois; and the Middle Woodland Garden Creek site in North Carolina. In both cases, integrating geophysical methods throughout the archaeological investigations has resulted in multiple phases of generating and addressing new research objectives. Although clearly beneficial at these two mound sites in southeast USA, this interdisciplinary approach has obvious implications well beyond these temporal and geographical areas

Beyond Never-Never Land: Integrating LiDAR and Geophysical Surveys at the Johnston Site, Pinson Mounds State Archaeological Park, Tennessee, USA

Archaeologists often use near-surface geophysics or LiDAR-derived topographic imagery in their research. However, rarely are the two integrated in a way that offers a robust understanding of the complex historical palimpsests embedded within a social landscape. In this paper we present an integrated aerial and terrestrial remote sensing program at the Johnston Site, part of the larger Pinson Mounds landscape in the American MidSouth. Our work at Johnston was focused on better understanding the history of human landscape use and change so that we can begin to compare the Johnston Site with other large Middle Woodland (200 BC-AD 500) ceremonial centers in the region. Our research allowed us to examine the accuracy of an early map of the Johnston Site made in the early 20th century. However, our integrated remote sensing approach allows us to go well beyond testing the usefulness of the map; it helps identify different uses of the site through time and across space. Our research emphasizes the importance of an integrated remote sensing methodology when examining complex social landscapes of the past and present

Beyond Never-Never Land: Integrating LiDAR and Geophysical Surveys at the Johnston Site, Pinson Mounds State Archaeological Park, Tennessee, USA

Archaeologists often use near-surface geophysics or LiDAR-derived topographic imagery in their research. However, rarely are the two integrated in a way that offers a robust understanding of the complex historical palimpsests embedded within a social landscape. In this paper we present an integrated aerial and terrestrial remote sensing program at the Johnston Site, part of the larger Pinson Mounds landscape in the American MidSouth. Our work at Johnston was focused on better understanding the history of human landscape use and change so that we can begin to compare the Johnston Site with other large Middle Woodland (200 BC-AD 500) ceremonial centers in the region. Our research allowed us to examine the accuracy of an early map of the Johnston Site made in the early 20th century. However, our integrated remote sensing approach allows us to go well beyond testing the usefulness of the map; it helps identify different uses of the site through time and across space. Our research emphasizes the importance of an integrated remote sensing methodology when examining complex social landscapes of the past and present

Building bridges between global information systems on marine organisms and ecosystem models

To facilitate the wider implementation of ecosystem modeling platforms and, thereby, to help advance ecosystem-based fisheries management (EBFM) worldwide, tools delivering a large quantity of inputs to ecosystem models are needed. We developed a web application providing OSMOSE ecosystem models with values for trophic, growth and reproduction parameters derived from data from two global information systems (FishBase and SeaLifeBase). Our web application guides the user through simple queries to extract information from FishBase and SeaLifeBase data archives, and it delivers all the configuration files necessary for running an OSMOSE model. Here, we present our web application and demonstrate it for the West Florida Shelf ecosystem. Our software architecture can serve as a basis for designing other advanced web applications using FishBase and SeaLifeBase data in support of EBFM