An Edited Collection of Resources Built by Learners, for Learners

Word Count: 20284

Included H5P activities: 126

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This is a calculus-based physics textbook meant for the type of freshman survey course taken by engineering and physical science majors, or for AP Physics C. It uses a nontraditional order of topics, with energy coming before force. For instructors who prefer the traditional sequence, there is a drop-in replacement for ch. 0-4, Mechanics, that covers force before energy. My text for the type of course usually taken by biology majors is Light and Matter.

"Sinergia Científica: Integrando las Ciencias desde una Perspectiva Multidisciplinaria" es un compendio de estudios que abarcan diversas disciplinas, uniendo la ciencia en un esfuerzo colectivo para resolver problemas complejos. El primer capítulo presenta una innovación en la cuyicultura sostenible, explorando la suplementación alimenticia con harina de amaranto y cúrcuma en cuyes. El segundo capítulo se adentra en el ámbito social, analizando los Derechos Humanos desde la perspectiva de las poblaciones vulnerables. En el tercer capítulo, se introduce un enfoque innovador en ingeniería civil, utilizando polímeros reciclados para el diseño de revestimientos de cunetas. El cuarto capítulo examina el impacto económico de la facturación electrónica en el sector de imprentas, un avance tecnológico crucial en la era digital. Finalmente, el quinto capítulo explora la influencia del neuromarketing en la rentabilidad de las PYMES, uniendo la neurociencia y el marketing para optimizar las estrategias comerciales. Este libro es un testimonio de cómo la integración multidisciplinaria puede conducir a soluciones innovadoras y sostenibles.

Edited by Caitlin Finlayson, Ph.D.

Word Count: 91292

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The goals of this textbook are to help students acquire the technical skills of using software and managing a database, and develop research skills of collecting data, analyzing information and presenting results. We emphasize that the need to investigate the potential and practicality of GIS technologies in a typical planning setting and evaluate its possible applications. GIS may not be necessary (or useful) for every planning application, and we anticipate these readings to provide the necessary foundation for discerning its appropriate use. Therefore, this textbook attempts to facilitate spatial thinking focusing more on open-ended planning questions, which require judgment and exploration, while developing the analytical capacity for understanding a variety of local and regional planning challenges.
While this textbook provides the background for understanding the concepts in GIS as applicable to urban and regional planning, it is best when accompanied by a hands-on tutorial, which will enable readers to develop an in-depth understanding of the specific planning applications of GIS. Chapters in this text book are either composed by the editors using Creative Common materials, or linked to a book chapter scanned copy in the library reserve. In the end of each chapter, we also provided several discussion questions, together with contextual applications through some web links.

Short Description:
This supplementary first-year physics textbook explores the role of language, alongside figures and mathematical symbols, in solving physics problems. The aim of this textbook is to help students gain extended, practical awareness of the roles of language in solutions to a range of first-year physics problems. The learning is guided mainly by comparing how language is used in formal, written solutions and in students' problem-solving dialogues. With new awareness how and why language is used in these two central forms of university physics practice, students can more effectively communicate solutions and guide their development as physicists and users of scientific English. After introducing problem-solving strategies and foundational aspects of language, the textbook guides students in the three primary functions of language in solutions: to represent concepts and phenomena, organize messages to facilitate their interpretation, and evaluate knowledge claims. Learning is largely task-based, emerging from completing the textbook tasks and reviewing feedback. The textbook is recommended for use alongside first-year physics instruction in self-guided study or instructor-facilitated contexts such as physics tutorials and English for physics courses.

Long Description:
This textbook combines the perspectives of physics and language to help you solve first-year physics problems and communicate your problem-solving choices more consciously and effectively. From the view of physics, the units present physics problems linked to the set of physics concepts typically taught in first year, focusing on how students with various physics competencies solve problems in dialogue and report their solutions in writing. By exploring the various competencies involved in solving physics problems and illustrating these competencies in solutions produced by students with different strengths and weaknesses, this textbook aims to help you understand and develop your own competencies.

A language perspective on learning first-year physics

The perspective of language complements the learning in physics because language systems are a key resource for thinking through and solving physics word problems. Language use in specialized activities such as solving physics problems tends to form identifiable patterns, implying that some language choices are more effective than others. Working through this textbook, you will observe the systems of language choices available for solving physics problems and develop capacities to use language more mindfully and effectively in your physics work.

Physics knowledge is produced, exchanged, and assessed in two main forms in first year courses, in speech and writing. In each textbook unit, a problem is introduced that requires application of one or more focal physics concepts, exploring spoken and written solutions to this problem to help you improve the effectiveness of solutions in both forms. Each unit also focuses on a specific function or sub-function of language, such as how concepts are represented or how solutions are organized, which is explored by comparing the spoken and written modes of communicating physics.

Across the 14 units, the textbook describes and explains the functional scope of the English language in shaping valued physics knowledge. For example, we explore the use of particular functional structures of English that physicists typically use when a problem requires us to re-interpret the concrete, physical world in terms of abstract concepts, such as when modelling a running person (concrete) as a point mass (concept).

The language perspective helps us answer questions such as these: What are the functions of language in solving physics problems? How does language help us to shift perspectives between a problem’s dynamic, physical situation and the stable, theoretical concepts involved? What are the roles of visual figures and mathematical symbolism relative to language in solving physics problems? What language choices are involved in effectively solving a physics problem in group dialogue and writing? Can we distinguish between reporting and explaining our solution? If so, how? What does it mean for a solution to be effectively communicated?

The knowledge and experiences you build in this course about the role of language in physics will help you to meet your expectations for solving physics problems and those of your peers and instructors. This aim is achieved in combination with the increased awareness and development of your competencies in solving physics problems. The guiding aim of this textbook is for you to apply the knowledge and experiences you gain towards your personal and professional development according to your interests in physics and science.

The organization of the textbook

The roles of language in solving physics problems are explored in increasing detail across the textbook units. Unit 1 provides the foundational perspectives on physics and language. The focus for learning is on strategies for solving word problems and the units and scales of language use in communicating the solutions.

Units 2 to 14 focus on physics concepts typically covered in first year, from motion along a straight line to fluid dynamics. Each unit introduces a problem developed to apply the unit’s focal concept and explores with you the solutions to these in spoken and written forms. A second problem is then introduced in the unit as an opportunity to apply, assess, and reflect on what you’ve learned.

Ways to use the textbook

The focus of this textbook is on improving your use of language, problem-solving strategies, and physics concepts in solving problems. As such, this book is not intended to replace a physics first-year textbook. Rather, this textbook is designed to be used in combination with a standard first-year physics textbook or course, where the methods and concepts are covered in detail.

This textbook is designed for first-year Science or Applied Science programs, where it would be used in (1) the tutorial section of the physics course focusing on problem-solving competencies and communicating solutions or in (2) a linked content-and-language syllabus such as an English for First-Year Physics course. This textbook will also find good use in (3) advanced placement high-school science programs, (4) pre-sessional university preparation programs, and (5) refresher courses for first-year physics. The book was designed especially for multilingual students of physics; however, it is expected to interest any physics enthusiasts with an interest in explicit understanding and extended practice of the language of physics.

The course is designed to be used in self-guided learning, peer study groups, or instructor-led classes. Whatever approach you take, learning through this textbook happens through your active engagement with the tasks. The task-based design involves a cycle of pre-task preparation, task activity, and post-task checking of responses and reflection. The post-task checking of your responses is crucial as this is typically where the effectiveness of your task performance is explained, that is, where the teaching emerges in dialogue with your input.

This course also includes optional features for deeper engagement and community-building around the language of solving physics problems. Chief among these features is the sharing of physics problems and solutions produced by you, the textbook users. As a user of the online textbook, you are invited to submit your solutions to the collection and compare these in terms of language features against our analyses of how language is used across all submissions. Users are also encouraged to design and share unique problems that reflect their particular interests and curiosities within and beyond physics. As the collection grows, so will the analyses, opportunities for engagement, and the learning community.

Word Count: 6443

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This a textbook on special relativity, aimed at undergraduates who have already completed a freshman survey course. The treatment of electromagnetism assumes previous exposure to Maxwell's equations in integral form, but no knowledge of vector calculus.

The Special Theory of Relativity is a theory of classical physics that was developed at the end of the nineteenth century and the beginning of the twentieth century. It changed our understanding of older physical theories such as Newtonian Physics and led to early Quantum Theory and later the Theory of General Relativity. Special Relativity is one of the foundation blocks of physics.

This book will introduce the reader to, perhaps, the most profound discovery of the twentieth century and the modern world: the universe has at least four dimensions.

Spiral Physics is a research based introductory physics curriculum developed at Monroe Community College. There are several important features of this curriculum. It integrates text and workbook activities in a modular fashion, and arranges topics so that students receive repeated exposure to concepts with increased complexity. It makes use of alternative problem types, including goal-less problem statements, ranking tasks, and critical analysis tasks. It restricts the equation set available for student use and is designed to facilitate active learning. Spiral Physics is available for both the algebra-based and calculus-based introductory courses. Assessment of Spiral Physics via the FCI, MBT, and MPEX compare favorably with the best results reported in the literature.

Word Count: 17851

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Short Description:
This is an open-access lab manual for a historical geology lab focused on student observations. We have uploaded this book to Lulu Press so that you may have them print a copy for you. The cost is $19.67 plus shipping. We believe in free access to educational materials, therefore we collect no revenue from Lulu. The price you pay is simply the cost Lulu charges to print the materials for you. You can also download a printable PDF version to print on your own. Do you plan on using the lab manual? Have any questions, comments, suggestions, or notice an error? Please fill out our contact form and let us know!

Word Count: 132319

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Short Description:
In this course you’ll learn how to lead or participate in community engagement, without triggering fear and overwhelming others; practise critical self-awareness and self-reflection; and consider equity-based and decolonizing approaches.

Long Description:
Professionals working across public, private and community sectors are facing complex questions about how to prepare for and adapt to the unavoidable impacts of a changing climate. In the context of a growing climate emergency, how do we engage internal and external stakeholders, build lasting collaborative partnerships, and embed climate adaptation strategies into organizational priorities, when professional silos, scarce resources and competing demands can pose potent obstacles to the change that is urgently needed?

This course will provide you with skills to overcome barriers to action, mobilize knowledge and data effectively, and work across silos in genuine interdisciplinary and collaborative practice. You’ll learn how to lead or participate in community engagement, without triggering fear and overwhelming others; practise critical self-awareness and self-reflection; and consider equity-based and decolonizing approaches.

This course is designed for professionals looking to advance the intersecting work of climate action and adaptation, including planners, engineers, elected officials and community leaders. You will leave with practical and relevant skills to lead, accelerate and participate in the essential work of climate adaptation in your organization and community.

This course is part of the Adaptation Learning Network led by the Resilience by Design Lab at Royal Roads University. The project is supported by the Climate Action Secretariat of the BC Ministry of Environment & Climate Change Strategy and Natural Resources Canada through its Building Regional Adaptation Capacity and Expertise (BRACE) program. The BRACE program works with Canadian provinces to support training activities that help build skills and expertise on climate adaptation and resilience.

Word Count: 28195

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The discipline of structural geology studies the architecture of the solid Earth and other planets. Rock deformation patterns are exciting features beacause of their aesthetic beauty and their economic interest to man. Knowledge of the subsurface structure is vital for the success of a variety of engineering and mineral exploration pograms. A thorough understanding of rock structures is essential for strategic planning in the petroleum and mining industry, in construction operations, in waste disposal surveys and for water exploration. Deformation structures in the country rock are important further for locallizing hazard zones, such as potential rockslide masses, ground subsidence, and seismic faults. Research activities concentrate on rock defomation structures in he shallow continental crust.

Word Count: 17534

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Physical geography is the study of the earth's dynamic systems: its air, water, weather climate, landforms, rocks, soils, plants, ecosystems and biomes and how humans interact with the earth's systems. Physical geography is the study of the world around you. It will help you to understand why San Francisco is always cold and foggy, why we have earthquakes, and what causes seasons. Everyone, every day, interacts with the earth's dynamic systems. I challenge you to join me on an exploration of the complex, and exciting world in which you live!

Physical geography is the study of the earth's dynamic systems: its air, water, weather climate, landforms, rocks, soils, plants, ecosystems and biomes and how humans interact with the earth's systems. Physical geography is the study of the world around you. It will help you to understand why San Francisco is always cold and foggy, why we have earthquakes, and what causes seasons. Everyone, every day, interacts with the earth's dynamic systems. I challenge you to join me on an exploration of the complex, and exciting world in which you live!

Long Description:
Welcome to Astronomy, an OpenStax resource. This textbook was written to increase student access to high-quality learning materials, maintaining highest standards of academic rigor at little to no cost. About OpenStax OpenStax is a nonprofit based at Rice University, and it’s our mission to improve student access to education. Our first openly licensed college textbook was published in 2012 and our library has since scaled to over 25 books for college and AP® courses used by hundreds of thousands of students. OpenStax Tutor, our low-cost personalized learning tool, is being used in college courses throughout the country. Through our partnerships with philanthropic foundations and our alliance with other educational resource organizations, OpenStax is breaking down the most common barriers to learning and empowering students and instructors to succeed. About OpenStax resources Customization Astronomy is licensed under a Creative Commons Attribution 4.0 International (CC BY) license, which means that you can distribute, remix, and build upon the content, as long as you provide attribution to OpenStax and its content contributors. Because our books are openly licensed, you are free to use the entire book or pick and choose the sections that are most relevant to the needs of your course. Feel free to remix the content by assigning your students certain chapters and sections in your syllabus, in the order that you prefer. You can even provide a direct link in your syllabus to the sections in the web view of your book. Instructors also have the option of creating a customized version of their OpenStax book. The custom version can be made available to students in low-cost print or digital form through their campus bookstore. Visit your book page on OpenStax.org for more information. Errata All OpenStax textbooks undergo a rigorous review process. However, like any professional-grade textbook, errors sometimes occur. Since our books are web based, we can make updates periodically when deemed pedagogically necessary. If you have a correction to suggest, submit it through the link on your book page on OpenStax.org. Subject-matter experts review all errata suggestions. OpenStax is committed to remaining transparent about all updates, so you will also find a list of past errata changes on your book page on OpenStax.org. Format You can access this textbook for free in web view or PDF through OpenStax.org, and for a low cost in print. About Astronomy Astronomy is written in clear non-technical language, with the occasional touch of humor and a wide range of clarifying illustrations. It has many analogies drawn from everyday life to help non-science majors appreciate, on their own terms, what our modern exploration of the universe is revealing. The book can be used for either a one-semester or two-semester introductory course (bear in mind, you can customize your version and include only those chapters or sections you will be teaching.) It is made available free of charge in electronic form (and low cost in printed form) to students around the world. If you have ever thrown up your hands in despair over the spiraling cost of astronomy textbooks, you owe your students a good look at this one. Currency and accuracy Astronomy has information and images from the New Horizons exploration of Pluto, the discovery of gravitational waves, the Rosetta Mission to Comet C-G, and many other recent projects in astronomy. The discussion of exoplanets has been updated with recent information—indicating not just individual examples, but trends in what sorts of planets seem to be most common. Black holes receive their own chapter, and the role of supermassive black holes in active galaxies and galaxy evolution is clearly explained. Chapters have been reviewed by subject-matter experts for accuracy and currency. Flexibility Because there are many different ways to teach introductory astronomy, we have made the text as flexible as we could. Math examples are shown in separate sections throughout, so that you can leave out the math or require it as you deem best. Each section of a chapter treats a different aspect of the topic being covered; a number of sections could be omitted in shorter overview courses and can be included where you need more depth. And, as we have already discussed, you can customize the book in a variety of ways that have never been possible in traditional textbooks. Student-centered focus This book is written to help students understand the big picture rather than get lost in random factoids to memorize. The language is accessible and inviting. Helpful diagrams and summary tables review and encapsulate the ideas being covered. Each chapter contains interactive group activities you can assign to help students work in teams and pool their knowledge. Interactive online resources Interesting “Links to Learning” are scattered throughout the chapters, which direct students to online animations, short videos, or enrichment readings to enhance their learning. Also, the resources listed at the end of each chapter include links to websites and other useful educational videos. Feature boxes that help students think outside the box A variety of feature boxes within the chapters connect astronomy to the students’ other subjects and humanize the face of astronomy by highlighting the lives of the men and women who have been key to its progress. Besides the math examples that we’ve already mentioned, the boxes include: Making Connections. This feature connects the chapter topic to students’ experiences with other fields, from poetry to engineering, popular culture, and natural disasters. Voyagers in Astronomy. This feature presents brief and engaging biographies of the people behind historically significant discoveries, as well as emerging research. Astronomy Basics. This feature explains basic science concepts that we often (incorrectly) assume students know from earlier classes. Seeing for Yourself. This feature provides practical ways that students can make astronomical observations on their own. End-of-chapter materials to extend students’ learning Chapter Summaries. Summaries give the gist of each section for easy review. For Further Exploration. This section offers a list of suggested articles, websites, and videos so students can delve into topics of interest, whether for their own learning, for homework, extra credit, or papers. Review Questions. Review questions allow students to show you (or themselves) how well they understood the chapter. Thought Questions. Thought questions help students assess their learning by asking for critical reflection on principles or ideas in the chapter. Figuring For Yourself. Mathematical questions, using only basic algebra and arithmetic, allow students to apply the math principles given in the example boxes throughout the chapter. Collaborative Group Activities. This section suggests ideas for group discussion, research, or reports. Beautiful art program Our comprehensive art program is designed to enhance students’ understanding of concepts through clear and effective illustrations, diagrams, and photographs. Here are a few examples. How a Pulsar Beam Sweeps over Earth. Structure of the Milky Way Galaxy. Two Aspects of Plate Tectonics. Pluto Close Up. Additional resources Student and instructor resources We’ve compiled additional resources for both students and instructors, including Getting Started Guides, PowerPoint slides, and an instructor answer guide. Instructor resources require a verified instructor account, which you can apply for when you log in or create your account on OpenStax.org. Take advantage of these resources to supplement your OpenStax book. Community Hubs OpenStax partners with the Institute for the Study of Knowledge Management in Education (ISKME) to offer Community Hubs on OER Commons – a platform for instructors to share community-created resources that support OpenStax books, free of charge. Through our Community Hubs, instructors can upload their own materials or download resources to use in their own courses, including additional ancillaries, teaching material, multimedia, and relevant course content. We encourage instructors to join the hubs for the subjects most relevant to your teaching and research as an opportunity both to enrich your courses and to engage with other faculty. To reach the Community Hubs, visit https://www.oercommons.org/hubs/OpenStax. Partner resources OpenStax Partners are our allies in the mission to make high-quality learning materials affordable and accessible to students and instructors everywhere. Their tools integrate seamlessly with our OpenStax titles at a low cost. To access the partner resources for your text, visit your book page on OpenStax.org. About the authors Senior contributing authors Andrew Fraknoi, Foothill College Andrew Fraknoi is Chair of the Astronomy Department at Foothill College and served as the Executive Director of the Astronomical Society of the Pacific from 1978–1992. His work with the society included editing Mercury Magazine, Universe in the Classroom, and Astronomy Beat. He’s taught at San Francisco State University, Canada College, and the University of California Extension. He is editor/co-author of The Universe at Your Fingertips 2.0, a collection of teaching activities, and co-author of Solar Science, a book for middle-school teachers. He was co-author of a syndicated newspaper column on astronomy, and appears regularly on local and national radio. With Sidney Wolff, he was founder of Astronomy Education Review. He serves on the Board of Trustees of the SETI Institute and on the Lick Observatory Council. In addition, he has organized six national symposia on teaching introductory astronomy. He received the Klumpke-Roberts Prize of the ASP, the Gemant Award of the American Institute of Physics, and the Faraday Award of the NSTA. David Morrison, National Aeronautics and Space Administration David Morrison is a Senior Scientist at NASA Ames Research Center. He received his PhD in astronomy from Harvard, where he was one of Carl Sagan’s graduate students. He is a founder of the field of astrobiology and is known for research on small bodies in the solar system. He spent 17 years at University of Hawaii’s Institute for Astronomy and the Department of Physics and Astronomy. He was Director of the IRTF at Mauna Kea Observatory. Morrison has held senior NASA positions including Chief of the Ames Space Science Division and founding Director of the Lunar Science Institute. He’s been on science teams for the Voyager, Galileo, and Kepler missions. Morrison received NASA Outstanding Leadership Medals and the NASA Exceptional Achievement Medal. He was awarded the AAS Carl Sagan medal and the ASP Klumpke-Roberts prize. Committed to the struggle against pseudoscience, he serves as Contributing Editor of Skeptical Inquirer and on the Advisory Council of the National Center for Science Education. Sidney C. Wolff, National Optical Astronomy Observatories (Emeritus) After receiving her PhD from the UC Berkeley, Dr. Wolff was involved with the astronomical development of Mauna Kea. In 1984, she became the Director of Kitt Peak National Observatory, and was director of National Optical Astronomy Observatory. Most recently, she led the design and development of the 8.4-meter Large Synoptic Survey Telescope. Dr. Wolff has published over ninety refereed papers on star formation and stellar atmospheres. She has served as President of the AAS and the ASP. Her recently published book, The Boundless Universe: Astronomy in the New Age of Discovery, won the 2016 IPPY (Independent Publisher Book Awards) Silver Medal in Science. All three senior contributing authors have received the Education Prize of the American Astronomical Society and have had an asteroid named after them by the International Astronomical Union. They have worked together on a series of astronomy textbooks over the past two decades. Contributing authors John Beck, Stanford University Susan D. Benecchi, Planetary Science Institute John Bochanski, Rider University Howard Bond, Pennsylvania State University, Emeritus, Space Telescope Science Institute Jennifer Carson, Occidental College Bryan Dunne, University of Illinois at Urbana-Champaign Martin Elvis, Harvard-Smithsonian Center for Astrophysics Debra Fischer, Yale University Heidi Hammel, Association of Universities for Research in Astronomy Tori Hoehler, NASA Ames Research Center Douglas Ingram, Texas Christian University Steven Kawaler, Iowa State University Lloyd Knox, University of California, Davis Mark Krumholz, Australian National University James Lowenthal, Smith College Siobahn Morgan, University of Northern Iowa Daniel Perley, California Institute of Technology Claire Raftery, National Solar Observatory Deborah Scherrer, retired, Stanford University Phillip Scherrer, Stanford University Sanjoy Som, Blue Marble Space Institute of Science, NASA Ames Research Center Wes Tobin, Indiana University East William H. Waller, retired, Tufts University, Rockport (MA) Public Schools Todd Young, Wayne State College Reviewers Elisabeth R. Adams, Planetary Science Institute Alfred N. Alaniz, San Antonio College Charles Allison, Texas A&M University–Kingsville Douglas Arion, Carthage College Timothy Barker, Wheaton College Marshall Bartlett, The Hockaday School Charles Benesh, Wesleyan College Gerald B. Cleaver, Baylor University Kristi Concannon, King’s College Anthony Crider, Elon University Scott Engle, Villanova University Matthew Fillingim, University of California, Berkeley Robert Fisher, University of Massachusetts, Dartmouth Carrie Fitzgerald, Montgomery College Christopher Fuse, Rollins College Shila Garg, Emeritus, The College of Wooster Richard Gelderman, Western Kentucky University Lee Hartman, University of Michigan Beth Hufnagel, Anne Arundel Community College Francine Jackson, Brown University Joseph Jensen, Utah Valley University John Kielkopf, University of Louisville James C. Lombardi, Jr., Allegheny College Amy Lovell, Agnes Scott College Charles Niederriter, Gustavus Adolphus College Richard Olenick, University of Dallas Matthew Olmstead, King’s College Zoran Pazameta, Eastern Connecticut State University David Quesada, Saint Thomas University Valerie A. Rapson, Dudley Observatory Joseph Ribaudo, Utica College Dean Richardson, Xavier University of Louisiana Andrew Rivers, Northwestern University Marc Sher, College of William & Mary Christopher Sirola, University of Southern Mississippi Ran Sivron, Baker University J. Allyn Smith, Austin Peay State University Jason Smolinski, Calvin College Michele Thornley, Bucknell University Richard Webb, Union College Terry Willis, Chesapeake College David Wood, San Antonio College Jeremy Wood, Hazard Community and Technical College Jared Workman, Colorado Mesa University Kaisa E. Young, Nicholls State University

Word Count: 214753

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This textbook was developed as a result of a Round 12 Textbook Transformation Grant.

Enquêtes sur la population, les activités économiques, la scolarisation et la santé de la reproduction​

Long Description:
Comment les universités africaines peuvent-elles contribuer à la mise en place de systèmes d’information qui offrent aux gestionnaires locaux des outils leur permettant de soutenir leur plan de développement, de prendre des décisions statistiquement motivées et de procéder au suivi-évaluation des actions mises en œuvre? À travers une vingtaine de contributions, ce livre aborde les problématiques de la dynamique de la population et des familles, des activités économiques, de la scolarisation et de la santé de la reproduction des adolescents, adolescentes et jeunes de l’arrondissement de Tchaourou, au centre du Bénin. Au-delà de ces problématiques, les auteurs mettent en exergue l’expérience de l’École Nationale de la Statistique, de la Planification et de la Démographie (ENSPD) de l’Université de Parakou (Bénin) qui s’investit depuis quelques années à contribuer à la formation et au renforcement des capacités des communes béninoises en ressources humaines spécifiques, puis à mettre progressivement en place un système de production de données statistiques locales fiables et utilisables pour la prise de décisions éclairées.

Word Count: 101107

ISBN: 978-2-924661-44-4

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Climate Change in Narrative Film

Short Description:
Explores the history and impact of the “Cli-Fi Film,” or Climate Fiction Film, a sub-genre of narrative cinema that depicts, on some level, the effects of climate change on the Earth and its inhabitants.

Long Description:
Telling Stories to Save the World: Climate Change in Narrative Film explores – through text, images, and video – the history and impact of the “Cli-Fi Film,” or Climate Fiction Film, a subgenre of narrative cinema that depicts, on some level, the effects of climate change on the Earth and its inhabitants. This openly-licensed resource covers the following topics: overview of climate change; rationale for the focus on narrative, or feature, film; definition and context of the “Cli-Fi Film”; history and impact of major narrative films focused on climate change, from Soylent Green (1973) to Don’t Look Up (2021). The resource concludes with a consideration of the future direction of Cli-Fi Films. Along the way, learners read about the author and some effects of climate change on her own life, inspiring her to create this resource and hopefully inciting those who use it to action.

Word Count: 23112

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