Mary Norris Stephenville High School Stephenville ISD Dr. Lin Shao Assistant Professor Nuclear Engineering Texas A & M
Dr. Shao’s Current Active Projects Nuclear Fuel Radiation Tolerant Materials for In- core and Out-core Components Advanced Sensor and Devices Photoelectric Effects of Self Assembled Nanoparticles in Si Nanoparticles in Si Effects of Self Assembled Metal Nanoparticles in Si
Practical use of photoelectric effect. Solar Cells will be interesting to students. Designing with solar panels will allow me to introduce engineering processes to students.
Scientific Processes (1) (A) demonstrate safe practices during laboratory and field investigations; (2) (E) design and implement investigative procedures, including making observations, asking well-defined questions, formulating testable hypotheses, identifying variables, selecting appropriate equipment and technology, and evaluating numerical answers for reasonableness; (2) (H) make measurements with accuracy and precision and record data using scientific notation and International System (SI) units; (2) (I) identify and quantify causes and effects of uncertainties in measured data; (2) (J) organize and evaluate data and make inferences from data, including the use of tables, charts, and graphs; (2) (K) communicate valid conclusions supported by the data through various methods such as lab reports, labeled drawings, graphic organizers, journals, summaries, oral reports, and technology-based reports; and (2) (L) express and manipulate relationships among physical variables quantitatively, including the use of graphs, charts, and equations. (3) (E) research and describe the connections between physics and future careers;
Science Concepts (4) (A) generate and interpret graphs and charts describing different types of motion, including the use of real-time technology such as motion detectors or photogates; (B) describe and analyze motion in one dimension using equations with the concepts of distance, displacement, speed, average velocity, instantaneous velocity, and acceleration; (6) (D) demonstrate and apply the laws of conservation of energy and conservation of momentum in one dimension; (8) (A) describe the photoelectric effect and the dual nature of light; (8) (C) describe the significance of mass- energy equivalence and apply it in explanations of phenomena such as nuclear stability, fission, and fusion; and (8) (D) give examples of applications of atomic and nuclear phenomena such as radiation therapy, diagnostic imaging, and nuclear power and examples of applications of quantum phenomena such as digital cameras
Administer Pre-test during the first two weeks of school. During “down” days, give students packets of K’NEX kits (or other model kits) to familiarize themselves with building cars.
Video will be introduction to lesson
Introductory lecture. Give students specifications for design and constraints. Assign groups. Student Research
First noted by Edmund Bequerel in Albert Einstein described the photoelectric effect in In 1954, Bell Laboratories built the first photovoltaic module. During the 1960s the space industry used the technology aboard spacecraft.
Possible car, most expensive, least labor intensive Less expensive, much more labor intensive. K’NEX model, longest lasting, most design possibilities. Students will make sketch of their car ideas. All group members must agree. Receive materials for car. Build Car ge=shop.product_details&flypage=shop.flypag e&product_id=83&category_id=26&manufactu rer_id=0&option=com_virtuemart&Itemid=26 &vmcchk=1&Itemid=26
Implementation Phase: Students will attempt to measure speed of cars using LabQuest with a motion detector. Graph results and determine average speed. Determine what changes can be made with cars to increase average speed. Possible changes may be either in the car design or angle of solar panel.
Evaluation Phase Make changes to cars and measure speed. Follow-up results.
1. Albert Einstein received the Nobel Prize in 1921 for his work on a)relativity. b) the atomic bomb. c) the photoelectric effect. d) quantum physics. 2. Average velocity can be defined as: a) the total displacement divided by the time interval during which the displacement occurred. b) the rate of change of velocity c) the motion of an object falling with a constant acceleration.
George Wei Tianyi ChenJustin GeneralJosey Wallace Lin Shao, Lab Director Undergraduate Leanne Kristek Thank You!!! Dr. Shao and his staff have been incredibly welcoming and gracious. They have willingly taken time from their busy schedules to help and answer questions whenever I asked. George Wei Tianyi ChenJustin GeneralJosey Wallace Lin Shao, Lab Director M.S. students Undergraduate Lloyd Price
TAMU E 3 Program Texas Workforce Commission National Science Foundation