Using inquiry-focused reading, students will explore an anchor text and supporting resources to investigate the principles of transfer of energy with applications of the concept to solve real world problems.

The instructors will prepare a sample presentation and model for students the steps taken to go from a text to the final project. Students will learn annotations, two column notes, and citations, while learning about how chemistry is used to solve real world problems based on the instructor provided materials. The students will then apply those concepts to a different project assigned by the instructors and apply the same strategies to their own texts to demonstrate their application of learning to a different problem.

Over the course of the unit, students will explore a variety of resources to develop their knowledge of energy, measurement of energy, and energy transfer. They will expand their ability to use informational text to support their inquiry and research, explore scientific literature, and develop questions to determine how the application of energy transfer principles can be applied to solve real world problems.

Located in Newport, Oregon, Hatfield Marine Science Center plays an integral role in programs of marine and estuarine research and instruction, as a laboratory facility serving resident scientists, as a base for far-ranging oceanographic studies, and as a classroom for students. Site features information on courses, seminars, facilities, and current research. Education Programs section includes teacher and student resources. Resources applicable to local and distant educators.

This activity is a classroom demonstration activity in which students make predictions and explore the concepts and applications of heat transfer and heat absorption.

Discover how electricity can be converted into other forms of energy such as light and heat. Connect resistors and holiday light bulbs to simple circuits and monitor the temperature over time. Investigate the differences in temperature between the circuit with the resistor and the circuit using the bulb.

In this video adapted from the National Science Center, observe a demonstration to discover how helium gas is inert and hydrogen gas is reactive.

This video will describe the history of the atom starting with Democritus and Aristotle all the way to Erwin Schrodinger and Louis De Broglie

In this activity, students take a Home Energy Quiz to identify improvements that could make their homes more energy-efficient.

This is the project information for students to complete an original Chemistry experiment. It can be adapted to other areas in science. It guides students through the process and includes links to additional materials used.

The unit “mole” is used in chemistry as a counting unit for measuring the amount of something. One mole of something has 6.02×1023 units of that thing. The magnitude of the number 6.02×1023 is challenging to imagine. The goal of this lesson is for students to understand just how many particles Avogadro's Number truly represents, or, how big is a mole. This lesson is meant for students currently enrolled in a first or second year chemistry course. This lesson is designed to be completed within one approximately 1 hour class; however, completion of optional activities 4 and 5 may require a longer class period or part of a second class period. This lesson requires only pencil and paper, as the activities suggested in this video place an emphasis on helping students develop their “back of the envelope” estimation skills. In fact, calculators and other measuring devices are explicitly discouraged. However, students may require additional supplies (poster board, colored pencils, markers, crayons, etc.) for the final optional/assessment activity, which involves creating a poster to demonstrate the size of a mole of their favorite macroscopic object.

In this classic hands-on activity, learners estimate the length of a molecule by floating a fatty acid (oleic acid) on water. This lab asks learners to record measurements and make calculations related to volume, diameter, area, and height. Learners also convert meters into nanometers. Includes teacher and student worksheets but lacks in depth procedure information. The author suggests educators search the web for more complete lab instructions.

This inquiry lab activity allows the students to explore limiting reagents with a simple acid and base reaction.

This activity helps students understand how mixtures are formed. They will make predictions regarding the rate of mixing. Students should report that the variation of heated water and crushed sugar creates the shortest mixing time.

This writing assignment is in lieu of a laboratory activity during the discussion of nuclear chemistry within the general chemistry curriculum.

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This video is the second lesson in the How Cold Is Cold? BLOSSOMS series and examines the properties of materials under low temperature conditions. The video consists of a series of fascinating demonstrations with liquid nitrogen, which boils at 77K (-196 C -321 F). These demonstrations include the following: What goes up, may not come down; Is that supposed to be cold? - thermal insulation; Some properties of liquid nitrogen; Making ice cream - the slow way and the fast way; Try not to explode: expansion of liquid nitrogen and the ideal gas law; Making the air cold: phase changes and the affect on volume; No frozen fingers: the changes in mechanical properties; Resistivity at 77K; The magic magnet: the Meissner Effect; Cautions in using liquid nitrogen

SSAC Physical Volcanology module. Students build a spreadsheet to examine how magma viscosity varies with temperature, fraction of crystals, and water content using the non-Arrhenian VFT model.

This Flash animation describes how hybrid-electric vehicles (HEVs) combine the benefits of gasoline engines and electric motors and can be configured to obtain different objectives, such as improved fuel economy, increased power, or additional auxiliary power for electronic devices and power tools.

This illustrated essay from A Science Odyssey Web site explains the science behind radio waves, including the role of electrons and electromagnetic fields.

In this video segment adapted from Shedding Light on Science, observe demonstrations of the fundamental idea that light travels in straight lines.

Use the Sound Grapher to create visualizations of sound and learn about the frequency, wavelength, amplitude and velocity of sound waves.