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1 - 10 of 69 results for: CHEMENG

CHEMENG 12SC: An Exploration of Art Materials: The Intersection of Art and Science

There is growing interest in the intersection of art and science, whether from artists adapting technology to suit their visions or from scientists and engineers seeking to explain various visual effects. To take advantage of possible creative sparks at the art/science interface, it is necessary for fuzzies and techies to have some knowledge of the language used by the other side. This interface will be explored through examining approaches used by an artist and an engineer in the context of the materials science of cultural objects. In-class lectures, hands-on studio practice, and field trips will be used to illustrate these different perspectives. At the heart of the scientific approach is the notion that a cultural object, e.g., a painting, is a physical entity comprising materials with different physical properties and different responses to environmental stresses presented by light, heat, and water. In support of this outlook, in-class lectures and discussions will focus on the ba more »
There is growing interest in the intersection of art and science, whether from artists adapting technology to suit their visions or from scientists and engineers seeking to explain various visual effects. To take advantage of possible creative sparks at the art/science interface, it is necessary for fuzzies and techies to have some knowledge of the language used by the other side. This interface will be explored through examining approaches used by an artist and an engineer in the context of the materials science of cultural objects. In-class lectures, hands-on studio practice, and field trips will be used to illustrate these different perspectives. At the heart of the scientific approach is the notion that a cultural object, e.g., a painting, is a physical entity comprising materials with different physical properties and different responses to environmental stresses presented by light, heat, and water. In support of this outlook, in-class lectures and discussions will focus on the basic concepts of color, optics, mechanics, composite structures, and response of the object to environmental stress, and we will visit Bay Area museums to see how artists employ such techniques. The hands-on studio experience is designed to increase students' confidence and develop their appreciation of differences in materials. It is not necessary to have any artistic training, only a willingness to experiment. The in-class studio projects will include working with line and shadow; color, binders, and mordants; global sources of pigments; substrates and writing; and material failure. Students will make one technical presentation on a topic in one of the five areas relevant to a painting: color, optics, mechanics, composites, and stress response. In addition, they will prepare one essay on the issues surrounding the intersection of art and science. Finally, they will complete a project related to one of the thematic areas covered in the hands-on studio sessions and make a final oral presentation describing their project.
Terms: Sum | Units: 2 | UG Reqs: WAY-CE

CHEMENG 20: Introduction to Chemical Engineering (ENGR 20)

Overview of chemical engineering through discussion and engineering analysis of physical and chemical processes. Topics: overall staged separations, material and energy balances, concepts of rate processes, energy and mass transport, and kinetics of chemical reactions. Applications of these concepts to areas of current technological importance: biotechnology, energy, production of chemicals, materials processing, and purification. Prerequisite: CHEM 31.
Terms: Win | Units: 4 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-SMA

CHEMENG 31N: When Chemistry Meets Engineering

Preference to freshmen. Chemistry and engineering are subjects that are ubiquitous around us. But what happens when the two meet? Students will explore this question by diving into experimental problems that scientists and engineers have to face on a daily basis. Many processes that are taken for granted have been developed by understanding science at a very fundamental level and then applying it to large and important industrial processes. In this seminar, students will explore some of the basic concepts that are important to address chemical engineering problems through experimental work. Students will build materials for energy and environmental applications, understand how to separate mixtures into pure compounds, produce fuels, and will learn to look at the chemical properties of molecules that are part of daily life with a different eye.
Last offered: Winter 2023 | UG Reqs: WAY-SMA

CHEMENG 55: Foundational Biology for Engineers (ENGR 55)

Biology, physics, and chemistry are the substrates for the modern engineer. Whether you are interested in developing the next generation of medicines or would like the next material or catalyst you design to be inspired by solutions found in Nature, this course will deepen your knowledge of the foundational concepts in biology and enrich your engineering skills. We will introduce the physical principles that underlie the construction and function of living cells, the fundamental building block of life. Emphasis will be on systems, logic, quantitation, and mechanisms of the molecular processes utilized by all life on Earth. This course has no prerequisites, but prior completion of CHEM 31 or equivalent is highly recommended.
Terms: Aut | Units: 4 | UG Reqs: WAY-AQR, WAY-SMA

CHEMENG 60Q: Environmental Regulation and Policy

Preference to sophomores. How does government, politics and science affect environmental policy? We examine environmental policy including the precautionary principal, acceptable risks, mathematical models, and cost-effectiveness of regulation. You will learn how data is changing environmental regulation and how different administrations mold environmental policy in real-time. We examine the use of science and engineering, its media presentation and misrepresentation, and the effect of public scientific and technical literacy. You will learn how to participate in the process and effect change.
Last offered: Autumn 2020 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR

CHEMENG 65Q: Chemical Engineering for Sustainability

Do you want to make the world more sustainable? How will we address the tremendous challenges that climate change brings? How can we reduce carbon emissions and not have huge disruptions in society? This class is for anyone who wants to create sustainable alternatives to what we use every day: engineers, scientists, those in humanities and the arts. Everyone has a role to play in designing our future. We will learn how to make the world more sustainable by exploring the exciting new world of (chemical) engineering sustainability. We will discuss renewable diesel and jet fuels; synthetic meat; compostable plastics; building materials that save energy; direct capture of carbon from the air; biological pharmaceuticals; and advanced recycling operations. The class starts with a brief overview of the deep cuts in carbon emissions and other pollutants that will be needed. Then, we focus on how sustainable (chemical) engineering can provide a solution, visiting four companies who are changing more »
Do you want to make the world more sustainable? How will we address the tremendous challenges that climate change brings? How can we reduce carbon emissions and not have huge disruptions in society? This class is for anyone who wants to create sustainable alternatives to what we use every day: engineers, scientists, those in humanities and the arts. Everyone has a role to play in designing our future. We will learn how to make the world more sustainable by exploring the exciting new world of (chemical) engineering sustainability. We will discuss renewable diesel and jet fuels; synthetic meat; compostable plastics; building materials that save energy; direct capture of carbon from the air; biological pharmaceuticals; and advanced recycling operations. The class starts with a brief overview of the deep cuts in carbon emissions and other pollutants that will be needed. Then, we focus on how sustainable (chemical) engineering can provide a solution, visiting four companies who are changing the world. Students will leave the class with an appreciation of how sustainable (chemical) engineering can help address climate change's substantial challenges, and perhaps an internship with one of the companies we visit. High school chemistry (balancing a chemical equation) and high school physics (unit conversions) are recommended for this course.
Terms: Win | Units: 3 | UG Reqs: WAY-AQR
Instructors: Libicki, S. (PI)

CHEMENG 90Q: Dare to Care: Compassionate Design

Imagine yourself with your abundant creativity, intellect, and passion, but your ability to move or speak is diminished. How would you face the world, how would you thrive at Stanford, how would you relay to people your ideas and creations? How would you share yourself and your ideas with the world? There are more than 50 million individuals in America with at least one disability, and in the current world of design, these differences are often overlooked. How do we as designers empower people of diverse physical abilities and provide them with means of self-expression?In Compassionate Design, students from any prospective major are invited to explore the engineering design process by examining the needs of persons with disabilities. Through invited guests, students will have the opportunity to directly engage people with different types of disabilities as a foundation to design products that address problems of motion and mobility, vision, speech and hearing. For example, in class, st more »
Imagine yourself with your abundant creativity, intellect, and passion, but your ability to move or speak is diminished. How would you face the world, how would you thrive at Stanford, how would you relay to people your ideas and creations? How would you share yourself and your ideas with the world? There are more than 50 million individuals in America with at least one disability, and in the current world of design, these differences are often overlooked. How do we as designers empower people of diverse physical abilities and provide them with means of self-expression?In Compassionate Design, students from any prospective major are invited to explore the engineering design process by examining the needs of persons with disabilities. Through invited guests, students will have the opportunity to directly engage people with different types of disabilities as a foundation to design products that address problems of motion and mobility, vision, speech and hearing. For example, in class, students will interview people who are deaf, blind, have cerebral palsy, or other disabling conditions. Students will then be asked, using the design tools they have been exposed to as part of the seminar, to create a particular component or device that enhances the quality of life for that user or users with similar limitations.Presentation skills are taught and emphasized as students will convey their designs to the class and instructors. Students will complete this seminar with a compassionate view toward design for the disabled, they will acquire a set of design tools that they can use to empower themselves and others in whatever direction they choose to go, and they will have increased confidence and abilities in presenting in front of an audience.
Terms: Aut | Units: 3 | UG Reqs: WAY-EDP
Instructors: Moalli, J. (PI)

CHEMENG 100: Chemical Process Modeling, Dynamics, and Control

Mathematical methods applied to engineering problems using chemical engineering examples. The development of mathematical models to describe chemical process dynamic behavior. Analytical and computer simulation techniques for the solution of ordinary differential equations. Dynamic behavior of linear first- and second-order systems. Introduction to process control. Dynamics and stability of controlled systems. Prerequisite: CME 100 or MATH 51&52 | Corequisite: Chemeng 20
Terms: Win | Units: 4

CHEMENG 105: Applied Mathematics in Chemical Engineering

Applied Mathematics in Chemical Engineering

CHEMENG 110A: Introduction to Chemical Engineering Thermodynamics

Thermodynamics of single-component systems: laws of thermodynamics, thermodynamic properties, equations of state, properties of ideal and real fluids, phase transitions and phase equilibrium, design of thermodynamic processes including refrigeration and power cycles. This course is intended for undergraduate sophomores and juniors in engineering and/or the chemical sciences; first-year students require consent of instructor. Pre-/Corequisites: CHEM 33, PHYS 41, MATH 51 or CME 100.
Terms: Aut | Units: 4
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