Conclusions and Scientific Explanations
Given laboratory investigation data, students will determine the best conclusion based upon that data.
Measurement
Given investigation quantitative data, students will determine its degree of precision and/or accuracy and causes for uncertainties in measured data.
Scientific Models
Given a description or illustration of various models, students will describe how these models represent the natural world and evaluate the advantages and limitations of the models.
Newton's Law of Inertia
This resource provides instructional resources for Newton's First Law, the law of inertia.
Conservation of Momentum
This resource was created to support TEKS IPC(4)(E).
Newton's Law of Action-Reaction
This resource is to support TEKS (8)(6)(C), specifically the Newton's third law or the law of action-reaction.
Conservation of Resources
Given choices of natural resources and lab materials, students will select disposal and recycling methods that best conserve and protect our resources
Equipment for Biology
Given investigation scenarios, students will determine the equipment that best fits the procedure.
Homeostasis—Succession
Given scenarios, illustrations, or descriptions, the student will identify the process of ecological succession and the impact that succession has on populations and species diversity.
Scientific Notation
Given quantitative data students will express and manipulate chemical quantities using scientific notation.
Dimensional Analysis
Given quantitative data, students will express and manipulate quantities using dimensional analysis.
Cell Specialization and Differentiation
Given examples, descriptions, and illustrations, students will be able to describe the role of DNA, RNA, and environmental factors in cell differentiation.
Significant Figures
Given quantitative data, students will express and manipulate quantities using the correct number of significant figures.
Scientific Reasoning
Given information extracted from current events, news reports, journal articles, marketing, or promotional materials, students will evaluate the claims for validity.
The Bohr Model
Students will understand Bohr’s experimental design and conclusions that lead to the development of his model of the atom, as well as the limitations of his model.
Valence Shell Electron Pair Repulsion
Given illustrations or descriptions, students will predict the shape of molecules based upon the extent of the electron pair electrostatic repulsion.
Chemical Bonding: Metallic Bonds
Given scenarios or diagrams, students will describe the nature of metallic bonding and explain properties such as thermal and electrical conductivity, malleability, and ductility of metals.
Electron Configuration
Given descriptors, diagrams, and chemical symbols, students will use the periodic table to determine the electron configuration of neutral atoms.
Nomenclature: Covalent Compounds
Given descriptions, diagrams, or scenarios, students will write and name the chemical formulas of binary covalent compounds.
Ionic Bonds: Electron Dot Formulas
Given descriptions, diagrams, scenarios, or chemical symbols, students will model ionic bonds using electron dot formulas.