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Core Course Review Documentation Foundational Component Area: LIFE & PHYSICAL SCIENCES Component Area Option? No Yes – Cultural & Global Understanding Yes – Undergraduate Inquiry & Creativity Proposed Course: Electricity, Magnetism, & Optics (Phys 2644) Credit Hours: 4 (3 hours lecture, 1 hour lab) Proposed by: Jacqueline Dunn Date: January 14, 2013 Please document how the proposed course meets each of the following requirements. (You may provide a written explanation or copy and paste the appropriate information from the syllabus.) Content: Courses in this category focus on describing, explaining, and predicting natural phenomena using the scientific method. Electricity, Magnetism, & Optics covers the basic components of electromagnetic theory (including electrostatic forces, electric fields, magnetic forces, and magnetic fields), circuits, and optics. Applications involving energy delivery are also covered, as are select topics from modern physics (basic ideas from quantum mechanics and cosmology). Content is addressed through lectures, readings, problem assignments, and hands-on laboratory activities. SKILLS: Courses involve the understanding of interactions among natural phenomena and the implications of scientific principles on the physical world and on human experiences. Students will be able to: Derive electric fields and forces for different configurations of charges. Analyze basic circuits and design circuits that have specified characteristics. Derive magnetic fields and forces for different configurations. Understand the relationship between electromagnetic theory and light. Analyze basic optical configurations. Explain basic ideas from modern physics including relativity and quantum mechanics and their applications. ASSESSMENT OF CORE OBJECTIVES: Assessments should be authentic, intentional and direct. The following four Core Objectives must be addressed in each course approved to fulfill this category requirement: Critical Thinking Skills - to include creative thinking, innovation, inquiry, and analysis, evaluation and synthesis of information Critical thinking skills are developed through course readings, lectures, and group problem sessions. The specific assessment used in this course (see attachment in this file) is the Brief Electricity and Magnetism Assessment (BEMA), which is administered to students at the end of the semester. Students will be evaluated to see if they have exceeded the benchmark level of the AACU VALUE Rubric for Critical Thinking (attached). Students also answer conceptual questions on an ongoing basis, similar to those contained in the critical thinking skills assessment. Communication Skills - to include effective development, interpretation and expression of ideas through written, oral, and visual communication Oral communication skills are developed through preparation of PowerPoint presentations discussing various forms of energy production. Students are assigned to work on a 5 to 10 minute PowerPoint presentation in groups of about 5 students covering the physics and social and political impacts of one method of energy production (see attachment in this file). Students will be evaluated to see if they have exceeded the benchmark level of the Assessment for Communication Skills Rubric (see attachment in this file), which focuses on Visual Communication, and has been created based on the AACU VALUE Rubrics for Oral and Written Communication (attached). Empirical and Quantitative Skills - to include the manipulation and analysis of numerical data or observable facts resulting in informed conclusions Empirical analytical skills and quantitative skills are developed through assigned readings, group problem sessions, and laboratory activities (students complete 10 laboratory assignments). The specific assessment used in this course (see attachment in this file) is to have students work in groups to solve assigned problems in class. Students will be evaluated to see if they have exceeded the benchmark level of the AACU VALUE Rubric for Quantitative Literacy (attached in this file). Teamwork - to include the ability to consider different points of view and to work effectively with others to support a shared purpose or goal Teamwork skills are developed through group projects and problem sessions. The specific assessment used in this course will be the team presentation on energy production mentioned under communication skills. Students are assigned to work on a 5 to 10 minute PowerPoint presentation in groups of about 5 students covering the physics and social and political impacts of one method of energy production. Students will be evaluated to see if they have exceeded the benchmark level of the AACU VALUE Rubric for Teamwork (attached in this file). ADDITIONAL INFORMATION: Provide any additional information supporting course inclusion in the core (optional). PLEASE ATTACH THE FOLLOWING 1. Syllabus 2. 3. 4. 5. Assessment for Critical Thinking Skills Assessment for Communication Skills Assessment for Empirical & Quantitative Skills Assessment for Teamwork Phys 2644 – Physics II (Electricity, Magnetism, & Optics) MWF 11:00 am – 11:50 am, McCoy 207 Instructor: Jackie Dunn Office: McCoy 219D Office Phone: 4184 Email: jackie.dunn@mwsu.edu Textbook: Fundamentals of Physics, 9th Edition by Halliday & Resnick (ISBN: 978-0-470-54789-2) Office Hours: MWF 8:00 – 8:50 am, 10:00 – 10:50 am, and 12:00 – 12:50 pm, F 1:00 – 1:50 pm Lab: M 4:00 – 5:50 pm, T 1:00 – 2:50 pm, T 3:00 – 4:50 pm, W 2:00 – 3:50 pm, R 3:00 – 4:50 pm Grading: Labs – 15%, Participation – 15%, Exams (2 @ 20% each) – 40%, Final – 30% Course Website: on Blackboard / WebCT Course Description: This course is designed to introduce the student to the basic concepts of physics. We will cover electricity and magnetism, as well as introductory optics. Attendance: While attendance is not factored into your grade directly, you must attend class regularly if you hope to do well. Tests can only be made up if you have an excused absence (illness counts only if you can provide a doctor’s note). Any planned absences from class should be discussed with the instructor beforehand if you are going to be missing a graded activity (e,g, test, quiz, etc.) so that make-up plans (if approved) may be arranged. Excused absences include university sponsored events, illness (documentation required showing you saw a doctor – you do not need to disclose why) and the death of an immediate family member (parents, children, siblings, etc.). Class participation points cannot be made up (not even with an excused absence). The grading scale for the participation points is as follows, according to the total percentage of points earned: 80% or more = 15 points, 70% to 80% = 12 points, 60% to 70% = 9 points, 50% to 60% = 6 points, 40% to 50% = 3 points, below 40% = 0 points. Please try to arrive to class on time (or even a couple minutes early) as we will start right away. If you must come in late (better to come in later than to miss an entire class), please do not be disruptive. Lab: All lab assignments must be completed during the lab period unless otherwise noted. If you cannot attend your normal section at any time, please try to attend the other section of the same week. Lab space is limited so be aware that if you attend a section other than your own, you may have to stand the entire time. If you miss a lab and cannot attend another section, you must make arrangements with the TA to makeup the lab. Expectations: Students should look over the chapters to be covered on a particular day prior to coming to class. It is recommended that you follow along in the notes during class. Cheating and plagiarism will not be tolerated. You may work together in pairs in lab, but you must submit your own work. Homework will be assigned on a regular basis, but will not be collected. Please turn off your cell phone (or put in silent mode) while in lecture or lab. If you must take a call during class (prohibited during exams and quizzes), please leave the room first so you do not disrupt the class. Note: In accordance with the law, MSU provides students with documented disabilities academic accommodations. If you are a student with a disability, please contact me. Note: By enrolling in this course, the student expressly grants MSU a "limited right" in all intellectual property created by the student for the purpose of this course. The "limited right" shall include but shall not be limited to the right to reproduce the student's work product in order to verify originality and authenticity, and for educational purposes. Exams: Exams will be held on the dates listed below. cumulative. Exam 1: Monday February 13, 2012 Exam 2: Wednesday March 7, 2012 Final Exam: Monday May 7, 2012 @ 10:30 am Topics to be Covered: Electric Charge and Electric Field Gauss’s Law Electric Potential Capacitance, Dielectrics, Electric Energy Storage Electric Currents and Resistance DC Circuits Magnetism Sources of Magnetic Field Electromagnetic Induction and Faraday’s Law Induction, Electromagnetic Oscillations, and AC Circuits Maxwell’s Equations and Electromagnetic Waves Light: Reflection and Refraction Lenses and Optical Instruments The final exam will be Assessment for Critical Thinking Skills The Brief Electricity and Magnetism Assessment (BEMA), developed by L. Ding, R. Chabay, B. Sherwood, and R. Beichner, is administered to students at the end of the semester. The BEMA has been administered at universities across the nation since 2006 to assess students understanding of basic electromagnetic concepts. The exam consists of 30 multiple choice questions. Since the exam must be kept secure, only a few sample questions may be reproduced here. Assessment for Communication Skills Students are assigned to work on a 5 to 10 minute PowerPoint presentation in groups of about 5 students covering the physics and social and political impacts of one method of energy production (nuclear, wind, solar, fossil fuels, etc.). Presentation Rubric (specific to this assignment): Points Content 5 Appropriate amount of content to fill the allotted time. 3 Slightly less or more content than what was needed for the allotted time (under or over by less than a two minutes). Creativity Uses graphics appropriately and often. May make use of props. Speaks to audience. No significant breaks in speech. Conducted in a professional manner. Uses graphics appropriately, but doesn’t include any extras (no props). Loses train of thought but recovers well. Conducted in a less serious manner (too many jokes, not formal enough, etc.) or reads straight from paper. One or two slight problems in descriptions of physical principals or exclusion of one physical concept that should have been addressed. Able to answer all questions posed with little difficulty or makes slight mistake in answering questions posed. Style Physics Answering Questions All physical concepts are described correctly and the appropriate concepts are addressed. Able to answer all questions posed without difficulty. 1 Significantly less or more content than what was needed for the allotted time (under or over by more than two minutes). Little or no graphics. Rarely or never makes eye contact with audience. May treat entire talk as a joke. Not professional at all. Major problems with physical descriptions or leaves out large component of the physical principals involved. Unable to adequately answer questions posed. Assessment for Empirical & Quantitative Skills Students should be able to answer the following problems without difficulty. (1) Derive Coulomb’s law from Gauss’ law. (2) Three positive point charges Q are arranged with one charge at each of three corners of a square of side L. What is the potential at the fourth corner, taking V=0 at infinity? (3) Three identical resistors R are connected in parallel with a battery. Draw the circuit and find the equivalent resistance. (4) A vertical straight wire carrying an upward 28 A current exerts an attractive force per unit length of 7.8 x 10-4 N/m on a second parallel wire 7.0 cm away. What current (magnitude and direction) flows in the second wire? (5) List all of the components of the electromagnetic spectrum, from the shortest wavelength to the longest wavelength. Indicate which component has the highest energy. The AACU quantitative literacy rubric is applied (copied below). Capstone 4 Milestones 3 2 Benchmark 1 Interpretation Ability to explain information presented in mathematical forms (e.g., equations, graphs, diagrams, tables, words) Provides accurate explanations of information presented in mathematical forms. Makes appropriate inferences based on that information. For example, accurately explains the trend data shown in a graph and makes reasonable predictions regarding what the data suggest about future events. Provides accurate explanations of information presented in mathematical forms. For instance, accurately explains the trend data shown in a graph. Provides somewhat accurate explanations of information presented in mathematical forms, but occasionally makes minor errors related to computations or units. For instance, accurately explains trend data shown in a graph, but may miscalculate the slope of the trend line. Attempts to explain information presented in mathematical forms, but draws incorrect conclusions about what the information means. For example, attempts to explain the trend data shown in a graph, but will frequently misinterpret the nature of that trend, perhaps by confusing positive and negative trends. Representation Ability to convert relevant information into various mathematical forms (e.g., equations, graphs, diagrams, tables, words) Skillfully converts relevant information into an insightful mathematical portrayal in a way that contributes to a further or deeper understanding. Competently converts relevant information into an appropriate and desired mathematical portrayal. Completes conversion of information but resulting mathematical portrayal is only partially appropriate or accurate. Completes conversion of information but resulting mathematical portrayal is inappropriate or inaccurate. Calculation Calculations attempted are essentially all successful and sufficiently comprehensive to solve the problem. Calculations are also presented elegantly (clearly, concisely, etc.) Calculations attempted are essentially all successful and sufficiently comprehensive to solve the problem. Calculations attempted are either unsuccessful or represent only a portion of the calculations required to comprehensively solve the problem. Calculations are attempted but are both unsuccessful and are not comprehensive. Application / Analysis Ability to make judgments and draw appropriate conclusions based on the quantitative analysis of data, Uses the quantitative analysis of data as the basis for deep and thoughtful judgments, drawing insightful, Uses the quantitative analysis of data as the basis for competent judgments, drawing reasonable and Uses the quantitative analysis of data as the basis for workmanlike (without inspiration or nuance, ordinary) Uses the quantitative analysis of data as the basis for tentative, basic judgments, although is hesitant or while recognizing the limits of this analysis carefully qualified conclusions from this work. appropriately qualified judgments, drawing conclusions from this plausible conclusions work. from this work. uncertain about drawing conclusions from this work. Assumptions Ability to make and evaluate important assumptions in estimation, modeling, and data analysis Explicitly describes assumptions and provides compelling rationale for why each assumption is appropriate. Shows awareness that confidence in final conclusions is limited by the accuracy of the assumptions. Explicitly describes assumptions and provides compelling rationale for why assumptions are appropriate. Explicitly describes assumptions. Attempts to describe assumptions. Communication Expressing quantitative evidence in support of the argument or purpose of the work (in terms of what evidence is used and how it is formatted, presented, and contextualized) Uses quantitative information in connection with the argument or purpose of the work, presents it in an effective format, and explicates it with consistently high quality. Uses quantitative information in connection with the argument or purpose of the work, though data may be presented in a less than completely effective format or some parts of the explication may be uneven. Uses quantitative information, but does not effectively connect it to the argument or purpose of the work. Presents an argument for which quantitative evidence is pertinent, but does not provide adequate explicit numerical support. (May use quasiquantitative words such as "many," "few," "increasing," "small," and the like in place of actual quantities.) Assessment for Teamwork Students are assigned to work on a 5 to 10 minute PowerPoint presentation in groups of about 5 students covering the physics and social and political impacts of one method of energy production (nuclear, wind, solar, fossil fuels, etc.). The AACU teamwork rubric is applied (copied below). Capstone 4 3 Milestones Contributes to Team Meetings Helps the team move forward by articulating the merits of alternative ideas or proposals. Offers alternative solutions or courses of action that build on the ideas of others. Offers new suggestions to advance the work of the group. Shares ideas but does not advance the work of the group. Facilitates the Contributions of Team Members Engages team members in ways that facilitate their contributions to meetings by both constructively building upon or synthesizing the contributions of others as well as noticing when someone is not participating and inviting them to engage. Engages team members in ways that facilitate their contributions to meetings by constructively building upon or synthesizing the contributions of others. Engages team members in ways that facilitate their contributions to meetings by restating the views of other team members and/or asking questions for clarification. Engages team members by taking turns and listening to others without interrupting. Individual Contributions Outside of Team Meetings Completes all assigned tasks by deadline; work accomplished is thorough, comprehensive, and advances the project. Proactively helps other Completes all assigned tasks by deadline; work accomplished is thorough, comprehensive, and advances the project. Completes all assigned tasks by deadline; work accomplished advances the project. Completes all assigned tasks by deadline. 2 Benchmark 1 team members complete their assigned tasks to a similar level of excellence. Fosters Constructive Team Climate Supports a constructive team climate by doing all of the following: • Treats team members respectfully by being polite and constructive in communication . • Uses positive vocal or written tone, facial expressions, and/or body language to convey a positive attitude about the team and its work. • Motivates teammates by expressing confidence about the importance of the task and the team's ability to accomplish it. • Provides assistance and/or encouragement to team members. Supports a constructive team climate by doing any three of the following: • Treats team members respectfully by being polite and constructive in communication . • Uses positive vocal or written tone, facial expressions, and/or body language to convey a positive attitude about the team and its work. • Motivates teammates by expressing confidence about the importance of the task and the team's ability to accomplish it. • Provides assistance and/or encouragement to team members. Supports a constructive Supports a constructive team climate by team climate by doing any doing any two of the one of the following: following: • Treats team • Treats team members members respectfully by respectfully by being polite and being polite constructive in and communication. constructive in • Uses positive communication vocal or written . tone, facial • Uses positive expressions, vocal or and/or body written tone, language to facial convey a positive expressions, attitude about the and/or body team and its language to work. convey a • Motivates positive teammates by attitude about expressing the team and confidence about its work. the importance • Motivates of the task and teammates by the team's ability expressing to accomplish it. confidence • Provides about the assistance and/or importance of encouragement the task and the to team team's ability members. to accomplish it. • Provides assistance and/or encouragement to team members. Responds to Conflict Addresses destructive conflict directly and constructively, helping to manage/resolve it in a way that strengthens overall team cohesiveness and future effectiveness. Identifies and acknowledges conflict and stays engaged with it. Redirecting focus Passively accepts alternate toward common ground, viewpoints/ideas/opinions. toward task at hand (away from conflict).
