Assessment Frameworks
II.I.I: Understand the properties, underlying structure, and reactions of matter.
II.I.I.PM: Properties of Matter
II.I.I.PM.1: Classify matter in a variety of ways (e.g., element, compound, mixture; solid, liquid, gas; acidic, basic, neutral).
pH Analysis
pH Analysis: Quad Color Indicator
II.I.I.PM.2: Identify, measure, and use a variety of physical and chemical properties (e.g., electrical conductivity, density, viscosity, chemical reactivity, pH, melting point).
Circuit Builder
Density Experiment: Slice and Dice
Density Laboratory
II.I.I.PM.4: Describe trends in properties (e.g., ionization energy or reactivity as a function of location on the periodic table, boiling point of organic liquids as a function of molecular weight).
II.I.I.SM: Structure of Matter
II.I.I.SM.5: Understand that matter is made of atoms and that atoms are made of subatomic particles.
II.I.I.SM.6: Understand atomic structure, including:
II.I.I.SM.6.a: most space occupied by electrons
II.I.I.SM.6.b: nucleus made of protons and neutrons
II.I.I.SM.6.c: isotopes of an element
II.I.I.SM.7: Explain how electrons determine the properties of substances by:
II.I.I.SM.7.a: interactions between atoms through transferring or sharing valence electrons
Covalent Bonds
Electron Configuration
Ionic Bonds
II.I.I.SM.7.b: ionic and covalent bonds
II.I.I.SM.8: Make predictions about elements using the periodic table (e.g., number of valence electrons, metallic character, reactivity, conductivity, type of bond between elements).
Covalent Bonds
Electron Configuration
Ionic Bonds
II.I.I.SM.9: Understand how the type and arrangement of atoms and their bonds determine macroscopic properties (e.g., boiling point, electrical conductivity, hardness of minerals).
Covalent Bonds
Electron Configuration
Ionic Bonds
II.I.I.SM.10: Know that states of matter (i.e., solid, liquid, gas) depend on the arrangement of atoms and molecules and on their freedom of motion.
II.I.I.SM.11: Know that some atomic nuclei can change, including:
II.I.I.SM.11.a: spontaneous decay
II.I.I.SM.11.b: half-life of isotopes
II.I.I.SM.11.e: alpha, beta, and gamma radiation.
II.I.I.CR: Chemical Reactions
II.I.I.CR.13: Understand types of chemical reactions (e.g., synthesis, decomposition, combustion, redox, neutralization) and identify them as exothermic or endothermic.
Balancing Chemical Equations
Chemical Changes
Chemical Equations
Dehydration Synthesis
Equilibrium and Concentration
Titration
II.I.I.CR.14: Know how to express chemical reactions with balanced equations that show:
II.I.I.CR.14.a: conservation of mass
Balancing Chemical Equations
Chemical Equations
II.I.I.CR.14.b: products of common reactions.
Balancing Chemical Equations
Chemical Equations
II.I.I.CR.15: Describe how the rate of chemical reactions depends on many factors that include temperature, concentration, and the presence of catalysts.
II.I.II: Understand the transformation and transmission of energy and how energy and matter interact.
II.I.II.ET: Energy Transformation and Transfer
II.I.II.ET.1: Identify different forms of energy, including kinetic, gravitational (potential), chemical, thermal, nuclear, and electromagnetic.
Energy Conversion in a System
Energy of a Pendulum
Inclined Plane - Sliding Objects
Potential Energy on Shelves
Roller Coaster Physics
II.I.II.ET.2: Explain how thermal energy (heat) consists of the random motion and vibrations of atoms and molecules and is measured by temperature.
Energy Conversion in a System
Temperature and Particle Motion
II.I.II.ET.3: Understand that energy can change from one form to another (e.g., changes in kinetic and potential energy in a gravitational field, heats of reaction, hydroelectric dams) and know that energy is conserved in these changes.
Energy Conversion in a System
Energy of a Pendulum
Inclined Plane - Sliding Objects
Roller Coaster Physics
II.I.II.ET.4: Understand how heat can be transferred by conduction, convection, and radiation, and how heat conduction differs in conductors and insulators.
II.I.II.I: Interactions of Energy and Matter
II.I.II.I.9: Know that each kind of atom or molecule can gain or lose energy only in discrete amounts.
Bohr Model of Hydrogen
Bohr Model: Introduction
Star Spectra
II.I.II.I.10: Explain how wavelengths of electromagnetic radiation can be used to identify atoms, molecules, and the composition of stars.
II.I.II.I.11: Understand the concept of equilibrium (i.e., thermal, mechanical, and chemical).
Equilibrium and Concentration
Equilibrium and Pressure
II.I.III: Understand the motion of objects and waves, and the forces that cause them.
II.I.III.F: Forces
II.I.III.F.1: Know that there are four fundamental forces in nature: gravitation, electromagnetism, weak nuclear force, and strong nuclear force.
Free-Fall Laboratory
Gravitational Force
Pith Ball Lab
II.I.III.F.2: Know that every object exerts gravitational force on every other object, and how this force depends on the masses of the objects and the distance between them.
Gravitational Force
Pith Ball Lab
II.I.III.F.5: Explain how electric currents cause magnetism and how changing magnetic fields produce electricity (e.g., electric motors, generators).
Electromagnetic Induction
Magnetic Induction
II.I.III.F.6: Represent the magnitude and direction of forces by vector diagrams.
Coulomb Force (Static)
Pith Ball Lab
II.I.III.F.7: Know that when one object exerts a force on a second object, the second object exerts a force of equal magnitude and in the opposite direction on the first object (i.e., Newton’s Third Law).
II.I.III.M: Motion
II.I.III.M.8: Apply Newton's Laws to describe and analyze the behavior of moving objects, including:
II.I.III.M.8.a: displacement, velocity, and acceleration of a moving object
Atwood Machine
Fan Cart Physics
II.I.III.M.8.b: Newton’s Second Law, F = ma (e.g., momentum and its conservation, the motion of an object falling under gravity, the independence of a falling object’s motion on mass)
2D Collisions
Air Track
Atwood Machine
Fan Cart Physics
II.I.III.M.8.c: circular motion and centripetal force.
II.I.III.M.10: Describe wave propagation using amplitude, wavelength, frequency, and speed.
Longitudinal Waves
Refraction
Ripple Tank
II.I.III.M.11: Explain how the interactions of waves can result in interference, reflection, and refraction.
Basic Prism
Longitudinal Waves
Refraction
Ripple Tank
Sound Beats and Sine Waves
II.I.III.M.12: Describe how waves are used for practical purposes (e.g., seismic data, acoustic effects, Doppler effect).
Doppler Shift
Doppler Shift Advanced
Longitudinal Waves
II.II.I: Understand how the survival of species depends on biodiversity and on complex interactions, including the cycling of matter and the flow of energy.
II.II.I.EC: Ecosystems
II.II.I.EC.1: Know that an ecosystem is complex and may exhibit fluctuations around a steady state or may evolve over time.
Coral Reefs 1 - Abiotic Factors
II.II.I.EC.2: Describe how organisms cooperate and compete in ecosystems (e.g., producers, decomposers, herbivores, carnivores, omnivores, predator-prey, symbiosis, mutualism).
II.II.I.EC.3: Understand and describe how available resources limit the amount of life an ecosystem can support (e.g., energy, water, oxygen, nutrients).
Food Chain
Rabbit Population by Season
II.II.I.EC.4: Critically analyze how humans modify and change ecosystems (e.g., harvesting, pollution, population growth, technology).
Coral Reefs 1 - Abiotic Factors
Coral Reefs 2 - Biotic Factors
Pond Ecosystem
II.II.I.EF: Energy Flow in the Environment
II.II.I.EF.5: Explain how matter and energy flow through biological systems (e.g., organisms, communities, ecosystems), and how the total amount of matter and energy is conserved but some energy is always released as heat to the environment.
II.II.I.EF.6: Describe how energy flows from the sun through plants to herbivores to carnivores and decomposers.
II.II.I.EF.7: Understand and explain the principles of photosynthesis (i.e., chloroplasts in plants convert light energy, carbon dioxide, and water into chemical energy).
Cell Energy Cycle
Photosynthesis Lab
II.II.I.BD: Biodiversity
II.II.I.BD.8: Understand and explain the hierarchical classification scheme (i.e., domain, kingdom, phylum, class, order, family, genus, species), including:
II.II.I.BD.8.a: classification of an organism into a category
Dichotomous Keys
Human Evolution - Skull Analysis
II.II.I.BD.8.b: similarity inferred from molecular structure (DNA) closely matching classification based on anatomical similarities
Human Evolution - Skull Analysis
II.II.I.BD.8.c: similarities of organisms reflecting evolutionary relationships.
Human Evolution - Skull Analysis
II.II.I.BD.9: Understand variation within and among species, including:
II.II.I.BD.9.a: mutations and genetic drift
Evolution: Mutation and Selection
Evolution: Natural and Artificial Selection
II.II.I.BD.9.b: factors affecting the survival of an organism
Evolution: Mutation and Selection
II.II.I.BD.9.c: natural selection.
Evolution: Mutation and Selection
Evolution: Natural and Artificial Selection
Natural Selection
Rainfall and Bird Beaks - Metric
II.II.II: Understand the genetic basis for inheritance and the basic concepts of biological evolution.
II.II.II.G: Genetics
II.II.II.G.1: Know how DNA carries all genetic information in the units of heredity called genes, including:
II.II.II.G.1.a: the structure of DNA (e.g., subunits A, G, C, T)
II.II.II.G.1.b: information-preserving replication of DNA
II.II.II.G.2: Use appropriate vocabulary to describe inheritable traits (i.e., genotype, phenotype).
Chicken Genetics
Hardy-Weinberg Equilibrium
Mouse Genetics (One Trait)
Mouse Genetics (Two Traits)
II.II.II.G.3: Explain the concepts of segregation, independent assortment, and dominant/recessive alleles.
Mouse Genetics (One Trait)
Mouse Genetics (Two Traits)
II.II.II.G.4: Identify traits that can and cannot be inherited.
Hardy-Weinberg Equilibrium
Mouse Genetics (One Trait)
Mouse Genetics (Two Traits)
II.II.II.G.5: Know how genetic variability results from the recombination and mutation of genes, including:
II.II.II.G.5.a: sorting and recombination of genes in sexual reproduction result in a change in DNA that is passed on to offspring
Mouse Genetics (One Trait)
Mouse Genetics (Two Traits)
II.II.II.G.6: Understand the principles of sexual and asexual reproduction, including meiosis and mitosis.
Cell Division
Pollination: Flower to Fruit
II.II.II.G.7: Know that most cells in the human body contain 23 pairs of chromosomes including one pair that determines sex, and that human females have two X chromosomes and human males have an X and a Y chromosome.
II.II.II.BE: Biological Evolution
II.II.II.BE.9: Critically analyze the data and observations supporting the conclusion that the species living on Earth today are related by descent from the ancestral one-celled organisms.
Evolution: Mutation and Selection
II.II.II.BE.11: Understand that evolution is a consequence of many factors, including the ability of organisms to reproduce, genetic variability, the effect of limited resources, and natural selection.
Evolution: Mutation and Selection
Evolution: Natural and Artificial Selection
Microevolution
Rainfall and Bird Beaks - Metric
II.II.II.BE.12: Explain how natural selection favors individuals who are better able to survive, reproduce, and leave offspring.
Evolution: Mutation and Selection
Evolution: Natural and Artificial Selection
Microevolution
Natural Selection
Rainfall and Bird Beaks - Metric
II.II.III: Understand the characteristics, structures, and functions of cells.
II.II.III.SF: Structure and Function
II.II.III.SF.1: Know that cells are made of proteins composed of combinations of amino acids.
II.II.III.SF.2: Know that specialized structures inside cells in most organisms carry out different functions, including:
II.II.III.SF.2.a: parts of a cell and their functions (e.g., nucleus, chromosomes, plasma, and mitochondria)
Cell Structure
Human Karyotyping
Paramecium Homeostasis
RNA and Protein Synthesis
II.II.III.SF.2.c: similarities and differences between plant and animal cells
II.II.III.SF.2.d: prokaryotic and eukaryotic cells.
Cell Structure
Paramecium Homeostasis
II.II.III.SF.3: Describe the mechanisms for cellular processes (e.g., energy production and storage, transport of molecules, waste disposal, synthesis of new molecules).
Cell Structure
Osmosis
Paramecium Homeostasis
RNA and Protein Synthesis
II.II.III.SF.4: Know how the cell membrane controls which ions and molecules enter and leave the cell based on membrane permeability and transport (i.e., osmosis, diffusion, active transport, passive transport).
II.II.III.SF.6: Know that DNA directs protein building (e.g., role of RNA).
II.II.III.BM: Biochemical Mechanisms
II.II.III.BM.7: Describe how most cell functions involve chemical reactions, including:
II.II.III.BM.7.b: processes of respiration (e.g., energy production, ATP)
Cell Energy Cycle
Cell Structure
II.III.I: Examine the scientific theories of the origin, structure, contents, and evolution of the solar system and the universe, and their interconnections.
II.III.I.1: Understand the scale and contents of the universe, including:
II.III.I.1.b: objects in the universe such as planets, stars, galaxies, and nebulae.
II.III.I.2: Predict changes in the positions and appearances of objects in the sky (e.g., moon, sun) based on knowledge of current positions and patterns of movements (e.g., lunar cycles, seasons).
Moonrise, Moonset, and Phases
Seasons Around the World
Seasons in 3D
II.III.I.5: Explain how objects in the universe emit different electromagnetic radiation and how this information is used.
II.III.I.6: Describe how stars are powered by nuclear fusion, how luminosity and temperature indicate their age, and how stellar processes create heavier and stable elements that are found throughout the universe.
II.III.II: Examine the scientific theories of the origin, structure, energy, and evolution of Earth and its atmosphere, and their interconnections.
II.III.II.EE: Characteristics and Evolution of Earth
II.III.II.EE.3: Describe the internal structure of Earth (e.g., core, mantle, crust) and the structure of Earth’s plates.
II.III.II.EE.4: Understand the changes in Earth's past and the investigative methods used to determine geologic time, including:
II.III.II.EE.4.a: rock sequences, relative dating, fossil correlation, and radiometric dating
II.III.II.EE.5: Explain plate tectonic theory and understand the evidence that supports it.
II.III.II.ES: Energy in Earth's System
II.III.II.ES.7: Describe convection as the mechanism for moving heat energy from deep within Earth to the surface and discuss how this process results in plate tectonics, including:
II.III.II.ES.7.a: geological manifestations (e.g., earthquakes, volcanoes, mountain building) that occur at plate boundaries
II.III.II.ES.8: Describe the patterns and relationships in the circulation of air and water driven by the sun's radiant energy, including:
II.III.II.ES.8.c: global climate, global warming, and the greenhouse effect
Carbon Cycle
Greenhouse Effect - Metric
II.III.II.ES.8.d: El Niño, La Niña, and other climatic trends.
Coastal Winds and Clouds - Metric
Hurricane Motion - Metric
Weather Maps - Metric
II.III.II.GC: Geochemical Cycles
II.III.II.GC.9: Know that Earth’s system contains a fixed amount of natural resources that cycle among land, water, the atmosphere, and living things (e.g., carbon and nitrogen cycles, rock cycle, water cycle, ground water, aquifers).
Carbon Cycle
Cell Energy Cycle
Porosity
II.III.II.GC.10a: the major rock types (i.e., sedimentary, igneous, metamorphic) and their formation
II.III.II.GC.12: Explain how the availability of ground water through aquifers can fluctuate based on multiple factors (i.e., rate of use, rate of replenishment, surface changes, and changes in temperature).
Correlation last revised: 9/22/2020