This is a five-activity module that explores the evidence for and impacts of melting glacial ice, with resources from major institutions and scientists who study glaciers -- primarily in Arctic areas. The suite of activities includes both glaciers and melting ice, as well as the impact of melt water downstream. Each activity follows the 5E model of Engagement, Exploration, Explanation, Elaboration, and Evaluation.

This course provides an understanding of how geospatial perspectives and technologies support all stages of emergency management activities, from small scale emergency management efforts to large scale disaster/humanitarian efforts. This includes learning about commonly used and emerging geospatial tools. It also includes an exploration of advancements in data collection, processing and analysis capabilities, such as unmanned aerial systems, geospatial artificial intelligence, volunteered geographic information, social media, and many more.

Short Description:
Crafted on behalf of RbD by: Janis Brooks, Erynne Gilpin, Beth Cougler Blom, Robin Cox, Krista Lambert, & Brigit Forssman. Artwork by Nikki LaRock.

Long Description:
This course invites learners into deeper thinking, reflection and content pertaining to Indigenous perspectives in climate adaptation and mitigation.

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: 32822

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

This course covers the fundamental methods used for exploring the information content of observations related to kinematical and dynamical models.

In this course on the mathematics of infinite random matrices, students will learn about the tools such as the Stieltjes transform and Free Probability used to characterize infinite random matrices.

Inorganic chemistry is concerned with the properties and reactivity of all chemical elements. Advanced interests focus on understanding the role of metals in biology and the environment, the design and properties of materials for energy and information technology, fundamental studies on the reactivity of main group and transition elements, and nanotechnology. Synthetic efforts are directed at hydrogen storage materials and thermoelectrics, catalysts for solar hydrogen generation, fullerenes and metal porphyrins, metal clusters and compounds with element-element bonds, as well as nanowires and nanoparticles.

Adapted for CHEM 250, UBC-V

Short Description:
This open access book has been specifically adapted for CHEM 250, an interdisciplinary inorganic chemistry course at UBC-V, for Chemical Engineering students. The main objective of this book is to introduce students to the basic principles of inorganic chemistry and link them with current applications relevant to a chemical engineer. It is a comprehensive online resource for 2nd year undergraduate students everywhere as it will be available under the creative commons license and will be widely available in OER catalogues.

Long Description:
This text was adapted from Chemistry 2e available here: https://openstax.org/details/books/chemistry-2e

Word Count: 175430

ISBN: 978-1-947172-61-6

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

This course emphasizes concepts and techniques for solving integral equations from an applied mathematics perspective. Material is selected from the following topics: Volterra and Fredholm equations, Fredholm theory, the Hilbert-Schmidt theorem; Wiener-Hopf Method; Wiener-Hopf Method and partial differential equations; the Hilbert Problem and singular integral equations of Cauchy type; inverse scattering transform; and group theory. Examples are taken from fluid and solid mechanics, acoustics, quantum mechanics, and other applications.

This course uses reaction kinetics, batch reactor analysis, batch distillation, batch operations scheduling, safety analysis, and the ABACUSS process simulator to introduce process design and analysis techniques.
Acknowledgements
The materials for the Fall 2006 offering of this course were drawn extensively from the materials that Professor Paul Barton used while teaching this course in past years. We are indebted to him for his long service to 10.490.

This course introduces students to methods and background needed for the conceptual design of continuously operating chemical plants. Particular attention is paid to the use of process modeling tools such as Aspen that are used in industry and to problems of current interest. Each student team is assigned to evaluate and design a different technology and prepare a final design report.
For spring 2006, the theme of the course is to design technologies for lowering the emissions of climatically active gases from processes that use coal as the primary fuel.

This course provides a brief introduction to the field of biocatalysis in the context of process design. Fundamental topics include why and when one may choose to use biological systems for chemical conversion, considerations for using free enzymes versus whole cells, and issues related to design and development of bioconversion processes. Biological and engineering problems are discussed as well as how one may arrive at both biological and engineering solutions.

In the ICE-Topics courses, various chemical engineering problems are presented and analyzed in an industrial context. Emphasis is on the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies.
The broad context for this ICE-Topics module is the commonsense notion that, when designing something, one should plan for the off-normal conditions that may occur. A continuous process is conceived and designed as a steady-state operation. However, the process must start up, shut down, and operate in the event of disturbances, and so the time-varying behavior of the process should not be neglected. It is helpful to consider the operability of a process early in the design, when alternatives are still being compared. In this module, we will examine some tools that will help to evaluate the operability of the candidate process at the preliminary design stage, before substantial effort has been invested.

6.720 examines the physics of microelectronic semiconductor devices for silicon integrated circuit applications. Topics covered include: semiconductor fundamentals, p-n junction, metal-oxide semiconductor structure, metal-semiconductor junction, MOS field-effect transistor, and bipolar junction transistor. The course emphasizes physical understanding of device operation through energy band diagrams and short-channel MOSFET device design. Issues in modern device scaling are also outlined. The course is worth 2 Engineering Design Points.
Acknowledgments
Prof. Jesús del Alamo would like to thank Prof. Harry Tuller for his support of and help in teaching the course.

In this training, participants will be learning how to integrate computer science into their own classrooms. This scaffolded training will guide participants to eventually solve real-world problems and design their own lessons of integration. 

This course integrates studies of engineering sciences, reactor physics and safety assessment into nuclear power plant design. Topics include materials issues in plant design and operations, aspects of thermal design, fuel depletion and fission-product poisoning, and temperature effects on reactivity, safety considerations in regulations and operations, such as the evolution of the regulatory process, the concept of defense in depth, General Design Criteria, accident analysis, probabilistic risk assessment, and risk-informed regulations.

These interactive lecture slides cover topics in Galaxies and Cosmology, aligned with the the OpenStax Astronomy textbook. Topics cover chapters 1, 5, 6, 24-30, and sections of chapter 17 and 19 concerning distance. While aligned with topics in the textbook, slides are not a 1-to-1 mapping of the textbook and contain additional content, ideas, and discussion.

Opportunities for active engagement and interaction using peer instruction techniques (think-pair-share and discussion questions) are built into the slides. References to related activities and labs are also included. Slides are provided as Google Slides documents for easy adaptation. Each chapter has a complete version of the slides along with separated slides for different topics in the chapter.

This is one part of an astronomy resource collection by Lane Community College. This collection was built by Andrea Goering (goeringa@lanecc.edu) and Richard Wagner (wagnerr@lanecc.edu), instructors of physics and astronomy at Lane Community College in Eugene, Oregon, USA. Development of these resources was funded through LCC's OER Initiative (https://inside.lanecc.edu/oer). We'd love to hear about your use of these resources! Let us know what you're using, sign up for updates, and submit corrections, suggestions, or comments here: https://forms.gle/un49RUNs55GU3ZNF6

Find the full collection here: https://docs.google.com/spreadsheets/d/142FgVMDHZ7bu53gihe3kJ_-5PzsnuzfMklJ1ZLMFk2E/edit#gid=315930953

These interactive lecture slides cover topics in Solar System Astronomy, aligned with the OpenStax Astronomy textbook. Topics cover chapters 1-5, 6-13, and sections of 14 and 21 covering exoplanets. While aligned with topics in the textbook, slides are not a 1-to-1 mapping of the textbook and contain additional content, ideas, and discussion.

Opportunities for active engagement and interaction using peer instruction techniques (think-pair-share and discussion questions) are built into the slides. References to related activities and labs are also included. Slides are provided as Google Slides documents for easy adaptation. Each chapter has a complete version of the slides along with separated slides for different topics in the chapter.

This is one part of an astronomy resource collection by Lane Community College. This collection was built by Andrea Goering (goeringa@lanecc.edu) and Richard Wagner (wagnerr@lanecc.edu), instructors of physics and astronomy at Lane Community College in Eugene, Oregon, USA. Development of these resources was funded through LCC's OER Initiative (https://inside.lanecc.edu/oer). We'd love to hear about your use of these resources! Let us know what you're using, sign up for updates, and submit corrections, suggestions, or comments here: https://forms.gle/un49RUNs55GU3ZNF6

Find the full collection here: https://docs.google.com/spreadsheets/d/142FgVMDHZ7bu53gihe3kJ_-5PzsnuzfMklJ1ZLMFk2E/edit#gid=315930953

The lecture slides linked below cover a 10-week course on Stellar Astronomy using the OpenStax Astronomy textbook. Topics cover chapters 1, 2, 5, 15-23, and sections of chapter 24 concerning black holes. While aligned with topics in the textbook, slides are not a 1-to-1 mapping of the textbook and contain additional content, ideas, and discussion.

Opportunities for active engagement and interaction using peer instruction techniques (think-pair-share and discussion questions) are built into the slides. References to related activities and labs are also included. Slides are provided as Google Slides documents for easy adaptation. Each chapter has a complete version of the slides along with separated slides for different topics in the chapter.

This is one part of an astronomy resource collection by Lane Community College. This collection was built by Andrea Goering (goeringa@lanecc.edu) and Richard Wagner (wagnerr@lanecc.edu), instructors of physics and astronomy at Lane Community College in Eugene, Oregon, USA. Development of these resources was funded through LCC's OER Initiative (https://inside.lanecc.edu/oer). We'd love to hear about your use of these resources! Let us know what you're using, sign up for updates, and submit corrections, suggestions, or comments here: https://forms.gle/un49RUNs55GU3ZNF6

Find the full collection here: https://docs.google.com/spreadsheets/d/142FgVMDHZ7bu53gihe3kJ_-5PzsnuzfMklJ1ZLMFk2E/edit#gid=315930953

My name is Ahmed Malik and I am a 3rd year at the University of Chicago. I like to use visualizations/interactive elements to convey information in an aesthetic fashion. I believe that OpenStax can benefit from becoming more interactive, so I created an example of an interactive "textbook" and shared it with the OpenStax staff. They asked me to post it on this group so we can get more feedback. I would greatly appreciate all comments and ideas. My goal is to make something like this for all standard physics subjects, (mechanics, E&M, quantum mechanics, etc), and I believe it could even be applied to other subjects.

(PS: This is meant to be an interactive web experience, but I had issues posting it online, so I just recorded myself using it as another student would)

Short Description:
This book is meant to be a second course in fluid mechanics that stresses applications dealing with external potential flows and intermediate viscous flows. Students are expected to have some background in some of the fundamental concepts of the definition of a fluid, hydrostatics, use of control volume conservation principles, initial exposure to the Navier-Stokes equations, and some elements of flow kinematics, such as streamlines and vorticity. It is not meant to be an in-depth study of potential flow or viscous flow, but is meant to expose students to additional analysis techniques for both of these categories of flows. We will see applications to aerodynamics, with analysis methods able to determine forces on arbitrary bodies. We will also examine some of the exact solutions of the Navier-Stokes equations based on classical fluid mechanics. Finally we will explore the complexities of turbulent flows and how for boundary layer flows one can predict drag forces. This compilation is drafted from notes used in the course Intermediate Fluid Mechanics, offered to seniors and first year graduate students who have a background in mechanical engineering or a closely related area. Data Dashboard

Word Count: 105137

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)