DOCSLIB.ORG

BG Cover Project Atlantis

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
BG Cover Project Atlantis WMHSMUN XXXIV Project Atlantis Year 3000 Background Guide “Unprecedented committees. Unparalleled debate. Unmatched fun.” Letter From the Director Dear Delegates, My name is Anna Isler and I am thrilled to serve as your director for Project Atlantis! I am a junior at the college double majoring in Biology and Health Sciences. Outside of academics, I play the violin in the W&M Symphony Orchestra and a string quartet, conduct research on synthetic biology and genetic engineering, and, of course, I am a member of the International Relations Club. As a member of the club, I have worked with the philanthropy team, International Relations Cares, competed in and staffed conferences, and I am a member of the &MUN IX Secretariat. I was first introduced to MUN when I came to William & Mary, and I have enjoyed traveling to competitions and staffing ever since. I have been a fan of sci-fi and fantasy stories for as long as I can remember, and I’m excited to be able to bring elements of both genres into this committee. Right now, science and technology are progressing faster than ever, so who knows what could happen by the time we reach the year 3000. The unprecedented times we are living in right now also necessitate creative solutions to our world’s problems. I look forward to seeing your innovations shine in committee. Anna Isler [email protected] Background Guide – Project Atlantis Introduction Human life and society have changed drastically over the last 1000 years. Even with humanities best efforts, global warming continued, and our planet began to change. Earth’s temperatures have risen by approximately 5.4°C with water temperature increasing by 3°C. The oceans in the southern hemisphere rose 3m after the Antarctic Ice Sheet collapsed, flooding island nations and forcing their citizens to flee. Environmental refugees fled northward and inland to escape rising sea levels, extreme weather conditions, and natural disasters, causing overpopulation in what livable land there is left. Food scarcity is a looming threat as fertile land is becoming exhausted from centuries of unsustainable farming.1 Much of the 2000’s millennia was spent exploring space and trying to establish civilization beyond our planet. Even though space exploration and civilization is developing, it will not be enough to preserve humanity. Project Atlantis was dreamt up 10 years ago as the need for self-sufficient, alternative societies became serious. The UN Third Committee handpicked a team of 20 experts from around the world in fields ranging from law to geology to bring the project to life. Years of research have gone into creating pieces of the puzzle, now it is time to put everything together and start living under the sea. Setting The location chosen for Project Atlantis was inspired by Plato’s dialogues which said "For the ocean there was at that time navigable; for in front of the mouth which you Greeks call, as you say, 'the pillars of Heracles,' (i.e., Hercules) there lay an island which was larger than Libya and Asia together." We know now that it is geologically impossible for Atlantis to have existed in the Atlantic, however Plato’s history and philosophy about Atlantis paint an interesting picture about the city. Atlantis was not a perfect, utopian society as it is sometimes portrayed in modern media. Atlantis was a powerful, wealthy, and 2 Background Guide – Project Atlantis technologically advanced nation that became corrupted in its search for power and expansion. It is suspected that Atlantis was sunk by divine intervention after the gods became disgusted by the decline in Atlantean ethics. Keep these philosophies in mind while developing this civilization.2 The site for the Atlantis settlement is located beyond the Strait of Gibraltar in the Atlantic Ocean at a depth of 300m. This is an ideal location for an underwater settlement because it is well sheltered, and humans can adapt to the pressure and air quality differences from the surface. One technology that will revolutionize underwater settlements is the “Gravitational Pull Water Displacement System (GPWDS)” created by Vinny Santorini, a member of this committee. This technology was inspired by the way the moon’s gravitational pull influences the tides. Using GPWDS, a watertight dome can be created on the sea floor which will be reinforced with a plexiglass barrier. Breathable air can be pumped into the area until Atlantis has created its own air purification system. Committee members will not have to worry about fulfilling their basic needs during this experimental stay, but they should have created and tested strategies for self-sufficiency that can be applied once the Atlantis settlement is fully developed. Underwater Settlements Underwater settlements are, obviously, not a new idea. Underwater labs and experimental habitats were pioneered in the 1950’s and 60’s and research continued throughout the 2000’s millennia. Underwater hotel rooms and vacation locations were also popularized in the 21st century. The technology to create underwater societies has Aquarius Reef Base existed for centuries, and yet no one has been able to establish a long-term, sustainable settlement.3 Underwater labs were some of the first underwater facilities to house researchers, often called aquanauts. Most of these labs were made of multiple pods or modules made of steel, glass, and cement. Creating multiple connected modules was simpler than attempting to create a large dome structure, however GPDWS makes creating a “bubble” NOAA Hydrolab structure much easier. 3 Background Guide – Project Atlantis Inspiration for the possible structure of Atlantis was drawn from two ambitious ideas proposed by architects in the 21st century. The first is Phillip Pauley’s Sub-Biosphere 2 model. This housing network centers on a Central Support Biome which is surrounded by eight Living Biomes. The Central Support Biome controls necessary life systems Sub-Biosphere 2 Design including air, water, food, electricity, and pressure. It will also house a seed bank for growing hydroponic crops to feed the inhabitants. The entire structure is anchored to the sea floor. The Central Pod will rise above the water while the living biomes are submerged. Shimizu Corp., a Japanese architectural firm, developed a model for an underwater city contained in a 1,600-foot-wide sphere that could support up to 5,000 residents. The settlement would float just below the surface but can descend up to 9 miles below the surface in response to changing weather conditions. They also planned to establish a research facility connected to the city which would mine the seabed for precious metals and create energy for the city above. The city would be further supported by desalinated water using hydraulic pressure, fish farms built around the structure, and microorganisms to convert carbon dioxide into Shimzu Corp. Design methane energy.4 Agriculture Food supply is one the main issues currently affecting the terrestrial world. Underwater, there are many innovative models to sustainable food production. Fresh seafood and plankton are readily available, but still need to be cultivated and consumed sustainably. Unsustainable, mono aquaculture practices for farming fish cause red rides, diseases, and oxygen deficiency in the aquatic environments. Saltwater aquaponics is a system that has been researched recently as a sustainable way to reduce stress on environments used by conventional fish farms.5 Aquaponics combines aquaculture, conventional raising of aquatic animals, with hydroponics, cultivation plants in water, in a symbiotic environment. The system involves a tank for raising and feeding the aquatic creature, usually fish, and a hydroponic system where the plants are grown. The water in the fish tank accumulates food and waste from the fish, which is then pumped out of the fish tank, pushed through 4 Background Guide – Project Atlantis biofilters to catch large particles, and into the hydroponic system where the plants are grown. The nutrient rich water feeds the plants and the plants, in turn, clean the toxins of the water. The water is then pumped back into the fish tanks. Aquaponics removes the main pollutants caused by agricultural runoff, pesticides and fertilizers. Aquaponics creates a closed ecosystem which protects the plants from parasites and the system creates a natural fertilizer, so the system is completely safe and doesn’t leave a footprint on the aquatic ecosystem.6 Saltwater aquaponics systems can be used to cultivate abalone, scallops, seaweed, sea cucumbers, spinach, barley, rice, and swiss chard. Phytoplankton, zooplankton, and seaweed can be used as natural biofilters. One of the best ways to sustain an aquaponics system is to establish a food chain within the system. This means feeding the fish, or other aquatic organisms, with plants or organisms created within the system. GreenWave’s model (see image)7 is a great example of regenerative aquaponics that can be used to cultivate a variety of food in the ocean. Freshwater aquaponics systems can also be created by desalinating seawater.8 The gravitational pull technology that creates a water free dome can facilitate open air farming. Crops like carrots, potatoes, and tomatoes can grow quite well in sandy soil, however this open-air farming may not be sustainable for all underwater settlements. Maritime Relations Project Atlantis is a non-partisan body, but once the success of this settlement has been shared, how will underwater territories be established and regulated? The United Nations Law of the Sea Convention in 1982 extended international law to the ocean. This law established freedom of navigation rights, set territorial sea boundaries 12 miles offshore, set exclusive economic zones up to 200 miles offshore, set rules for extending continental shelf rights up to 350 miles offshore, created the International Seabed Authority, and created other committees like the UN Commission on the Limits of the Continental Shelf.
Load more

Recommended publications
  • Atlantic Origin of the Arctic Biota? Evidence from Phylogenetic and Biogeographical Analysis of the Cheilostome Bryozoan Genus Pseudoflustra
    Atlantic Origin of the Arctic Biota? Evidence from Phylogenetic and Biogeographical Analysis of the Cheilostome Bryozoan Genus Pseudoflustra Piotr Kuklinski1,2*, Paul D. Taylor2, Nina V. Denisenko3, Bjo¨ rn Berning4 1 Institute of Oceanology, Polish Academy of Sciences, Sopot, Poland, 2 Natural History Museum, London, United Kingdom, 3 Zoological Institute, Russian Academy of Sciences, St. Petersburg, Russia, 4 Geoscientific Collections, Upper Austrian State Museum, Leonding, Austria Abstract The intricate geological evolution of the Arctic Ocean is paralleled by complexities in the biogeographical and phylogenetical histories of the Arctic biota, including bryozoans. Here we present revised taxonomic descriptions for all known species of the bryozoan genus Pseudoflustra, and use the present-day distributions and phylogenetic relationships between these species to infer the historical biogeography of the genus. Nine species belonging to the genus Pseudoflustra are recognized in the Arctic and North Atlantic. One new species, previously identified as Ichthyaria aviculata, is described as Pseudoflustra radeki sp. nov. Another species, previously assigned to Smittoidea as S. perrieri, is transferred to Pseudoflustra. Biogeographical analysis of Pseudoflustra reveals that species distributions mostly match current patterns pertaining in the North Atlantic and Arctic Ocean. Distributions were probably shaped by recent geological history as present-day current directions in the Arctic Ocean are believed to have been similar for at least the last 120 000 years. Phylogenetic analysis of Pseudoflustra places the five Arctic-North Atlantic species in a clade crownward of a paraphyletic grouping of North Atlantic species. Given that the Arctic Ocean was fully glaciated until 18 000 years, the most likely explanation for this phylogeographical pattern is that species of Pseudoflustra colonized the Arctic relatively recently from North Atlantic sources.
    [Show full text]
  • Ocean Island Shore
    AN INTERDISCIPLINARY WORKSHOP PLACING THE GLOBAL PACIFIC IN THE AGE OF CLIMATE CHANGE SPEAKERS: WARWICK ANDERSON SUGATA BOSE WENJIAO CAI JASON O. CHANG OCEAN BATHSHEBA R. DEMUTH ALEXIS DUDDEN XIAOFEI GAO JOHN HAYASHI ISLAND STEFAN HUEBNER JOHN HUTH ANTHONY MEDRANO SHORE EDWARD MELILLO IAN J. MILLER PETER PERDUE HELEN ROZWADOWSKI JONAS RÜEGG CHRISTINA THOMPSON MICHAELA THOMPSON WEDNESDAY, MAY8, 2019 9:00 AM – 5:30 PM HUCE 440 Museum of Comparative Zoology 26 Oxford Street, Cambridge Co-sponsored by: Harvard Universit y Asia Center Fairbank Center for Chinese Studies The Pacific Circle OCEAN, ISLAND, SHORE: PLACING THE GLOBAL PACIFIC IN THE AGE OF CLIMATE CHANGE May 8 th, 2019 How did modern state and non-state actors go about transforming the Pacific into a political- economic frontier during the nineteenth and twentieth centuries? What environmental, territorial, and social changes did they bring about in the process? And how does applying a maritime framework to the intertwined histories of East Asia, Southeast Asia, and Oceania change our understanding of industrialization, imperialism, capitalism, and socialism in modern Asia? Our workshop explores the intensifying exploitation of marine resources off the coasts of Pacific Asia and Oceania during the nineteenth and twentieth centuries. The expansion of global industrial capitalism into Asia’s and Oceania’s maritime regions during the nineteenth century, as well as the emergence of its communist equivalent during the mid-twentieth century, turned the affected seas and islands into a lively and contested arena. Formerly inaccessible or irrelevant maritime spaces became targets of novel political and commercial expansion schemes, leading state and non-state actors alike to stake and defend new borders that went well beyond the traditional territorial edges of the region’s major states.
    [Show full text]
  • April-June 2010 1082-6491*April-June 2*ISSN Number 23 Volume
    AGAINST NAZI TERROR, INTERNATIONAL SOLIDARITY: No Nazis in L.A. April 17 Liberation and Human Rights for Communities in Struggle by Michael Novick, Anti-Racist Action-Los Angeles/People Against Racist Terror (ARA-LA/PART) The “National Socialist Movement” (NSM), a neo-nazi formation with a base in Open Nazis are not the main enemy in a struggle against colonialism, capitalism Riverside CA and units around the US, has issued a call for a national gathering of and imperialism, but they are a significant element, particularly in a period of their organization in Los Angeles. It features a rally on Saturday, April 17 at noon ongoing economic crisis and political instability within the belly of the beast. The on the lawn of L.A. City Hall, for which they have already applied for and received National Socialist Movement and similar open fascist forces are seeking greater a permit. They will be bringing a substantial number of uniformed nazi thugs and political legitimacy. They want greater influence within larger white nationalist and reactionary social and political forces, such as the anti-immigrant movement, the boneheads from around the US as part of their so-called “Reclaim the Southwest “tea-baggers,” and the re-emerging militia movement. An associate of the NSM in Campaign.” The NSM boasts of being the oldest and largest nazi outfit in the U.S., Phoenix is a Republican Party Committeeman, and a pal of anti-migrant Sheriff Joe but their public modus operandi is always hiding behind the skirts of the police. Arpaio. Another associate was recently busted in Louisville KY for posting a threat They pose a clear and serious threat of racist and sexist violence, which always to the life of the president on an NSM chat-site, “NewSaxon.” NSM members and follows open nazi organizing.
    [Show full text]
  • Patrimoine Et Territoire : Une Parenté Conceptuelle En Question Les Cahiers Du CFPCI
    Les Cahiers du CFPCI7 Patrimoine et territoire : une parenté conceptuelle en question Les Cahiers du CFPCI Une collection du Centre français du patrimoine culturel immatériel- Maison des Cultures du Monde dirigée par Séverine Cachat Cette édition en ligne est le prolongement du séminaire international intitulé « Les terri- toires du patrimoine culturel immatériel », organisé à Vitré les 5 et 6 octobre 2017 par le Centre français du patrimoine culturel immatériel, dans le cadre du 21e festival de l’Imaginaire, avec le soutien et la participation de la direction générale des Patrimoines, département du Pilotage de la recherche et de la Politique scientifique (ministère de la Culture), de la Ville de Vitré, et la collaboration du Centre Georges Chevrier de l’université de Bourgogne (devenu en mars 2020 le LIR3S – Laboratoire Interdisciplinaire de Recherche « Sociétés, Sensibilités, Soin »). Illustration de couverture : Couverture brodée par les insurgents de l’EZLN représentant l’hydre capitaliste, festival CompARTE por la Humanidad (« pARTage »), 2016. © Élie Kongs. Numéro coordonné par Jean-Louis Tornatore, Isabelle Chave et Séverine Cachat Relecture, traduction et mise en page Marie Guérinel Copyright 2020 Maison des Cultures du Monde-Centre français du patrimoine culturel immatériel Les Cahiers du CFPCI 7 Table des matières Introduction Patrimoine et territoire, limites et impasses d’une « parenté conceptuelle » ......................................................................................... 9 Jean-Louis Tornatore Partie 1 :
    [Show full text]
  • The Biogeography of the Plastisphere: Implications for Policy
    RESEARCH COMMUNICATIONS RESEARCH COMMUNICATIONS The biogeography of the Plastisphere: 541 implications for policy Linda A Amaral-Zettler1,2*, Erik R Zettler3, Beth Slikas1, Gregory D Boyd3, Donald W Melvin3, Clare E Morrall4, Giora Proskurowski5, and Tracy J Mincer6† Microplastics (particles less than 5 mm) numerically dominate marine debris and occur from coastal waters to mid-ocean gyres, where surface circulation concentrates them. Given the prevalence of plastic marine debris (PMD) and the rise in plastic production, the impacts of plastic on marine ecosystems will likely increase. Microscopic life (the “Plastisphere”) thrives on these tiny floating “islands” of debris and can be transported long distances. Using next-generation DNA sequencing, we characterized bacterial communities from water and plastic samples from the North Pacific and North Atlantic subtropical gyres to determine whether the composition of different Plastisphere communities reflects their biogeographic origins. We found that these communities differed between ocean basins – and to a lesser extent between polymer types – and displayed lat- itudinal gradients in species richness. Our research reveals some of the impacts of microplastics on marine bio- diversity, demonstrates that the effects and fate of PMD may vary considerably in different parts of the global ocean, and suggests that PMD mitigation will require regional management efforts. Front Ecol Environ 2015; 13(10): 541–546, doi:10.1890/150017 ublic awareness of plastic marine debris (PMD) and its Oberbeckmann et al. 2014). As annual plastic produc- Penvironmental impacts has intensified due in part to tion continues to increase (299 million metric tons in greater numbers of publications (both scholarly and popu- 2015 [PlasticsEurope 2015]), citizens, government agen- lar) and large-scale policy recommendations on the sub- cies, and the plastics industry are attempting to manage ject.
    [Show full text]
  • Becoming Marines in American Samoa
    Becoming Marines in American Samoa Disciplining mind and body in the making of a Marine Identity. Oddmund Toft Master thesis at the Department of Social Anthropology UNIVERSITY OF OSLO Spring 2018 II Becoming Marines in American Samoa: Disciplining mind and body in the making of a Marine identity. III © Oddmund Toft 2018 Becoming Marines in American Samoa: Disciplining mind and body in the making of a Marine identity. Oddmund Toft http://www.duo.uio.no/ Print: Reprosentralen, University of Oslo IV Abstract The territory of American Samoa in the southern Pacific, where I conducted fieldwork from January to June of 2017, has for many years been amongst the top places for recruiting personnel for the U.S. military. Everyone in American Samoa have a friend, sibling, family member or relative who are or have been in the military, and many use the military to gain access to education and money, and to help their family. In this thesis I explore the process of becoming U.S. Marines amongst a group of young people in American Samoa working to meet the requirements to go to boot camp. I argue that the time spent training for boot camp is simultaneously a period where they take the first steps towards acquiring the habitus and mindset of a Marine. I look at how they use shared values, brotherhood, as well as ways of thinking about progress, pain and how to live life, to create and maintain a shared identity as Marines. This topic is looked at through the lens of the body and the mind, and how they work together to create the Marine as a holistic and lifelong identity.
    [Show full text]
  • Floating Cities, Islands and States*
    1 Article Floating City 3 21 08 after Joseph Floating Cities, Islands and States* Alexander Bolonkin C&R, 1310 Avenue R, #F-6, Brooklyn, NY 11229, USA T/F 718-339-4563, [email protected], [email protected], http://Bolonkin.narod.ru Abstract Many small countries are in need of additional territory. They build landfills and expensive artificial islands. The ocean covers 71% of the Earth’s surface. Those countries (or persons of wealth) starting the early colonization of the ocean may obtain advantages through additional territory or creating their own independent state. An old idea is building a big ship. The best solution to this problem, however, is the provision of floating cities, islands, and states. The author’s idea is to use for floating cities, islands, and states a cheap floating platform created from a natural ice field taken from the Arctic or Antarctic oceans. These cheap platforms protected by air-film (bottom and sides) and a conventional insulating cover (top) and having a cooling system can exist for an unlimited time. They can be increased in number or size at any time, float in warm oceans, travel to different continents and countries, serve as artificial airports, harbors and other marine improvements, as well as floating cities and industrial bases for virtually any use. Author researches and computes parameters of these ice floating platforms, other methods of building such floating territory, compares them and shows that the offered method is the most cheap and efficient means of ocean colonization. ------------------------------- Key words: floating cities, ice floating platform, ocean colonization.
    [Show full text]
  • Illumin Article
    Sebastian Potes Dr. Elisa Warford Writing-340 6/11/13 Floating Cities: Settling the Sea and the New Frontier Abstract Many attempts have been made at building a floating city but only a few have been partially realized. Once thought to be a far off notion, the colonization of the ocean seems to be within reach. We will discuss a new method, proposed by scientist/engineer/inventor Alexander Bolonkin, that would create mobile, interlocking, floating ocean-platforms from which to build upon. This method, combined with an industry that would enable floating cities to flourish - the production of algae as biofuel - could lead to the next frontier. Introduction Ocean colonization is the theory and practice of permanent human settlements of oceans. These settlements may float freely on the ocean surface, be attached to the bottom of the ocean, or be somewhere in between [1]. The main reason for colonizing the ocean would be to expand the amount of livable area. Colonizing the surface of the ocean would also open up a whole new economy based on tourism, aquaculture (the farming of aquatic organisms such as fish, crustaceans, molluscs, and aquatic plants), and other ocean based industries. Ocean colonization would also provide a testing ground for space colonization. It seems that colonizing the ocean is simpler and would probably occur first. The lessons learned from running an ocean colony may prove useful to future outer space colonization efforts. Floating cities are not a new concept. In fact, similar communities already exist in the form of houseboats, oil platforms, hotels, and cruise ships (which are often called floating cities).
    [Show full text]
  • Distribution of Genetic Diversity Reveals Colonization Patterns And
    www.nature.com/scientificreports OPEN Distribution of genetic diversity reveals colonization patterns and philopatry of the loggerhead sea turtles across geographic scales Miguel Baltazar‑Soares1,2,12, Juliana D. Klein3,12, Sandra M. Correia4, Thomas Reischig5, Albert Taxonera6, Silvana Monteiro Roque7, Leno Dos Passos8, Jandira Durão9, João Pina Lomba10, Herculano Dinis11, Sahmorie J.K. Cameron1, Victor A. Stiebens1 & Christophe Eizaguirre1* Understanding the processes that underlie the current distribution of genetic diversity in endangered species is a goal of modern conservation biology. Specifcally, the role of colonization and dispersal events throughout a species’ evolutionary history often remains elusive. The loggerhead sea turtle (Caretta caretta) faces multiple conservation challenges due to its migratory nature and philopatric behaviour. Here, using 4207 mtDNA sequences, we analysed the colonisation patterns and distribution of genetic diversity within a major ocean basin (the Atlantic), a regional rookery (Cabo Verde Archipelago) and a local island (Island of Boa Vista, Cabo Verde). Data analysis using hypothesis‑driven population genetic models suggests the colonization of the Atlantic has occurred in two distinct waves, each corresponding to a major mtDNA lineage. We propose the oldest lineage entered the basin via the isthmus of Panama and sequentially established aggregations in Brazil, Cabo Verde and in the area of USA and Mexico. The second lineage entered the Atlantic via the Cape of Good Hope, establishing colonies in the Mediterranean Sea, and from then on, re‑colonized the already existing rookeries of the Atlantic. At the Cabo Verde level, we reveal an asymmetric gene fow maintaining links across island‑specifc nesting groups, despite signifcant genetic structure.
    [Show full text]
  • Decommissioning of Offshore Platform: a Sustainable Framework
    Decommissioning of Offshore Platform: A Sustainable Framework Decommissioning of Offshore Platform: A Sustainable Framework Commercial Diver in Oil and Gas Industry Concept Framework: Semi­PSS for Sustainable Decomissioning of Offshore Platformin Malaysia N.A.Wan Abdullah Zawawi, M.S. Liew & K.L.Na Department of Civil Engineering, Universiti Teknologi PETRONAS Bandar Seri Iskandar, 31750, Tronoh, Perak, Malaysia [email protected] Abstract ­ The decommissioning activities for fixed offshore platforms in Malaysia are expected to rise significantly. For many of the approximate 300 oil platforms, their service life is approaching the end. Thus far, only a handful of offshore platforms in Malaysian waters have been decommissioned mainly due to lack of regulatory framework and weak decommissioning plans. The shortage of decommissioning yards provides another major challenge in managing onshore disposal. With a number of options viable in decommissioning our used platforms, a review of these possibilities is timely. The scope of this paper entails the decommissioning methods particularly in the Gulf of Mexico, where conditions are similar to Malaysian waters. Evaluations of methodology as well as sustainability implications are discussed. The usual methods of decommissioning involve any of these options: complete removal, partial removal, reefing or re­using. Employing the aspects of sustainability as a pillar of the study, a conceptual framework of a viable decommissioning scheme is drawn. It was conceptually found that refurbishing the whole of the structure as a livable hub has its own unique potentials. Given the calm conditions of Malaysian waters and the sturdy design of the platforms, the restored structures hold possibilities either as ocean townships or futuristic cities such as a 'sea­stead'.
    [Show full text]
  • Colonies Lost Pier M
    Colonies Lost: God, Hunger, and Confl ict in Anosy (Madagascar) to 1674 VARIORUM VARIORUM Pier M. Larson fl eet of thirteen Portuguese vessels under the command of Pedro Álvares Cabral set sail from Lisbon for the East Indies just two years after Vasco da Gama fi rst rounded the Cape of Good Hope. In late May 1500, inclement weather at the Cape separated the vessel commanded by Diego Diaz from the others, blowing it well south of its intended course. Steering north to regain their way, Diaz and crew caught sight of land on 10 August along the coast of Anosy, Madagascar’s southeast extremity (fi g. 1). The day was the Feast of São Lourenço, and Diaz named the big island (Madagascar) for European cartography after the feast.1 As far as it is known, this was the fi rst sighting of Madagascar by seafarers hailing directly from the Atlantic via the Cape route. European sailors and mapmakers continued to identify Madagascar as São Lourenço (Portuguese) and Saint-Laurent (French) for centuries to come. From the early decades of the sixteenth century to the French abandonment of Madagascar in 1674, Anosy in southeast Madagascar was an important site of European-Malagasy interac- tion. The meeting grounds of Anosy played a signifi cant role in the early modern history of the southwest Indian Ocean, much as the Cape of Good Hope or Kilwa and Mombasa did, but they are poorly known outside a close circle of francophone Madagascar experts. At the same time little secondary literature on Anosy and its Europeans in any language is broad and compara- tive
    [Show full text]
  • Indigenous and Decolonizing Studies in Education
    INDIGENOUS AND DECOLONIZING STUDIES IN EDUCATION Indigenous and decolonizing perspectives on education have long persisted alongside colonial models of education, yet too often have been subsumed within the fields of multiculturalism, critical race theory, and progressive education. Timely and compelling, Indigenous and Decolonizing Studies in Education features research, theory, and dynamic foundational readings for educators and educational researchers who are looking for possibilities beyond the limits of liberal democratic schooling. Featuring original chapters by authors at the forefront of theorizing, practice, research, and activism, this volume helps define and imagine the exciting interstices between Indigenous and decolonizing studies and education. Each chapter forwards Indigenous principles—such as Land as literacy and water is life—that are grounded in place-specific efforts of creating Indigenous universities and schools, community organizing and social movements, trans and Two Spirit practices, refusals of state policies, and land-based and water-based pedagogies. Linda Tuhiwai Smith is a Professor of Māori and Indigenous Studies at the University of Waikato in New Zealand. Eve Tuck is Associate Professor of Critical Race and Indigenous Studies, Ontario Institute for Studies in Education, and Canada Research Chair of Indigenous Methodologies with Youth and Communities, University of Toronto. K. Wayne Yang is the Director of Undergraduate Studies in the Ethnic Studies Department at the University of California, San Diego. Indigenous and Decolonizing Studies in Education Series Editors: Eve Tuck and K. Wayne Yang Indigenous and Decolonizing Studies in Education Mapping the Long View Edited by Linda Tuhiwai Smith, Eve Tuck, and K. Wayne Yang INDIGENOUS AND DECOLONIZING STUDIES IN EDUCATION Mapping the Long View Edited by Linda Tuhiwai Smith Eve Tuck K.
    [Show full text]