This resource explores the cultural context of scientific inquiry through an interdisciplinary lens. Undergraduate students are invited to follow two characters from William Shakespeare’s play King Lear who debate the cosmos with various scientists from the 17th – 20th centuries, including Galileo Galilei, Isaac Newton, and Marie Curie. The joined scientific / literary lens models how intellectual questions about knowledge and analysis often draw from interrelated traditions of thought and practice, and asks students to consider the nature of their own intellectual questions. The resource is broken into five brief modules and can be completed entirely in class, or in partial increments as take-home.

This PBL is focused on students learning how to make inferences/conclusions about the main points in the article. It's also an engaging activity that teaches the students to be prepared, focused, and ready to learn.

Students will talk about fun events and things to do in Spanish speaking countries. They will practice how to reject or accept an invitation, emphasizing a polite way to explain why you can or can't go. They will also decide on ways to discuss what they did at an event or activity with friends.

Students will talk about fun events and things to do in Spanish speaking countries. They will practice how to reject or accept an invitation, emphasizing a polite way to explain why you can or can't go. They will also decide on ways to discuss what they did at an event or activity with friends.

Unlike film, theater in America does not have a ratings board that censors content. So plays have had more freedom to explore and to transgress normative culture. Yet censorship of the theater has been part of American culture from the beginning, and continues today. How and why does this happen, and who decides whether a play is too dangerous to see or to teach? Are plays dangerous? Sinful? Even demonic? In our seminar, we will study plays that have been censored, either legally or extra-legally (i.e. refused production, closed down during production, denied funding, or taken off school reading lists). We’ll look at laws, both national and local, relating to the “obscene”, as well as unofficial practices, and think about the way censorship operates in American life now. And of course we will study the offending texts, themselves, to find what is really dangerous about them, for ourselves.

This is a sample syllabus for a moral reasoning course that will explore the historical life of Jesus of Nazareth, analyzing his role, influence, and teachings. We will look at examples of his impact on the lives of other famous historical figures and consider how his moral philosophy can apply to our contemporary life.The course is designed for students of all traditions, backgrounds, and lifestyles. All faith views will be invited and encouraged to share in civil interfaith dialogue.

This independent experimental study course is designed to allow students with a strong interest in independent research to fulfill the project laboratory requirement for the Biology Department Program in the context of a research laboratory at MIT. The research should be a continuation of a previous project under the direction of a member of the Biology Department faculty.
This course provides instruction and practice in written and oral communication. Journal club discussions are used to help students evaluate and write scientific papers.

Students will identify how they, as individuals, think about climate science and explore common perceptions and misconceptions that exist about climate science. The activities within this unit incorporate individual reflection by students, small group work, and larger group/class discussions, and endeavor for students to learn how to discern true and untrue statements using logic and fact. Students are presented with various statements about climate science and are tasked with determining whether these statements are factually true and whether they are logically valid. We recognize that students may have limited background factual knowledge in climate science before starting these activities, so some exercises are intended more as a way for students to evaluate how they think about climate science and how to create logically valid scientific statements (i.e., how to think and talk like a scientist). By learning how to identify logically and factually true and untrue statements, students will, by the end of this unit, be able to create and evaluate statements about climate science (even with limited factual knowledge) and critique common misconceptions about climate science.

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In this introductory unit, students will learn about the fundamental role of observation by viewing photographs of both agricultural and non-agricultural (natural) landscapes and making independent observations. They will learn how to relate physiographic features to land use by drawing conclusions about how the physiography of the land affects or is affected by various land use practices. They will then discuss their observations in small groups, organize their thoughts, and explain their conclusions in a classroom oral presentation. Finally, students will consider landscape features in the context of Earth systems and discuss how these systems are impacted by human activity.

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In this unit, students engage in a scaffolded class discussion designed to encourage students to move from a broad focus on science relevancy to locally important societal issues relevant to soils. They then relate what they learned during this discussion to the major assessment of this module, the Soils, Systems, and Society Kit (the Kit) assignment, and begin exploring potential focal issues for this assignment. Lastly, the unit introduces concept mapping, and pre-service teachers create a starting concept map for Earth systems, which is a required element of the Kit.

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Unit 1 introduces the Water Sustainability in Cities Module. The content establishes the foundation definitions of sustainability, sustainable development, and water sustainability in cities. Key sustainability concepts are introduced and examples provided for water in cities. Students are engaged in activities to help them explore the definitions of water sustainability in cities and apply systems thinking. The unit materials are designed with flexibility in mind such that instructors can adapt the module to their own courses and context. The unit may also be used on its own to provide an introductory water sustainability lesson without using other units in the module.

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How are rising sea levels already influencing the developing nation of Bangladesh, and what are the anticipated consequences of additional sea level rise in the next century? This introduction to the Ice and Sea Level Changes module is designed to prompt student consideration of the economic, social, political, and health impacts of sea level change. They will revisit the impacts of sea level change on society in Unit 5 when they investigate implications for New York City and Southern California.

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Online-ready: This opening class discussion about climate change and societal impacts could be converted to an online discussion format.

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How have mass-wasting events affected communities, and what lessons have we learned from these natural disasters that might help us mitigate future hazards? In this unit, students answer these questions by being introduced to the landscape and societal characteristics that contributed to loss of property and life during the 1970 Nevado HuascarÃn (Peru) and 2010 San Fratello (Sicily, Italy) events.

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Online-ready: This opening class discussion about landslides and societal impacts could easily be converted to an online discussion format.

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This unit is designed to function as three days of instruction in an introductory urban planning, environmental science/studies or public health course.

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The introduction and examination of the food, energy, and water connection -- as a system in Unit 1 -- established the dictates of human dependency on and human modification of the environment. We continue a logical progression of what this means in Unit 2, with a focus on how people see, confront, and solve their resource challenges in the light of their need for affordable, accessible, healthy, sustainably-grown food. This unit introduces and explores the concepts, themes, and practices of: urban agriculture, urban farming, local food, food insecurity, food deserts, health & wellness education, community food gardens, community food dialogue, public policy, civic engagement, volunteerism, expert technical assistance, land reclamation, grants and incentives, entrepreneurship, and community economic development.

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In this unit, students will keep a log of immediate, personal sensory experiences by pausing once each hour over a period of ten hours and recording the sights, sounds, smells, tastes, and tactile experiences they are sensing at that moment. The log (or journaling activity) will occur outside of class and will be shared in a subsequent class meeting.
In class, students will exchange their logs, respond and discuss, and then form larger groups which will discuss disparate ways of paying attention to sensory experiences. Students will develop a deeper understanding of their own perceptions and how those perceptions can be recorded and used to evaluate an environmental setting. This activity is qualitative; it requires students to create an informal, subjective journal of their sensory experiences once each hour for a ten-hour time period prior to class.
When students share their individual qualitative experiences in pairs and small groups, they will begin to see patterns emerge that will enable them to develop quantitative observations for future use. They will also begin to relate their sensory experiences to the social, biological, and geophysical aspects of their personal environment; students will begin to explore how these system components are interrelated and how exposure to them may impact human experience and well-being. After the group discussion, students will reflect on the interstices between qualitative and quantitative analysis by way of their sensory logs and mutual discussion.

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Armed with an overview of the complexity of issues associated with global food security, this unit begins by contextualizing food security as an example of a wicked problem. Wicked problems are problems that are unsolvable in the traditional sense, and have complex multiscalar causal factors that contribute to the creation of new issues as old ones are addressed. Both global food security and climate change are examples of wicked problems. This unit presents systems thinking as a way to identify complex problems and explore solutions. Using a flipped classroom model, students complete a self study tutorial that presents system concepts in the context of Earth system science. The slide stack includes two guided activities related to the carbon cycle and soils. A short reading, "Why Systems Thinking?" and a video clip is included in the tutorial. Authentic assessment of the homework activity is an Earth system diagram connected to one of the issues of global food security from Unit 1 that they will bring to class. After a short class discussion that introduces concepts of sustainability and ecosystem services as related to food production, students are broken into groups and are asked to create their own systems diagram of the global food system, using the organizational systems concepts they examined as homework and the introduction activities of Unit 1. After completing the diagrams, students examine a food system diagram example, and identify the components of the system using standardized systems language. Students can photograph their diagrams or make quick sketches so they have a working copy to include with their notes.

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How have average global air temperature and sea level changed in the last three decades? Have the changes been consistent? Can future changes in air temperature and sea level be predicted? In this unit, students will become familiar with the concept of a time series by calculating recent air temperature and sea level trends and projecting these measurements for 2100. They will also begin to consider environmental factors in addition to temperature that could influence sea level and the potential implications of sea level changes during the next century.

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Online-adaptable: The lecture and main data analysis exercise can easily be moved online. Student discussions are designed to be intermixed into the flow of the lecture and exercise. Thus moving to online discussions would be might take a bit more planning.

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Students will be introduced to the concept of a natural cycle. They are first asked to identify the different components of the hydrologic cycle. Students will be able to recognize the delicate balance between the individual elements of a large and complex system. Students will also be able to identify the interactions among parts of a natural system.

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In this unit, students are introduced to the concept of a natural cycle. They are first asked to identify the different components of the hydrologic cycle in Spanish. Students will be able to recognize the delicate balance between the individual elements of a large and complex system. Students will also be able to identify the interactions among parts of a natural system.

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