Standards - Science

SC15.8.17

Create and manipulate a model of a simple wave to predict and describe the relationships between wave properties (e.g., frequency, amplitude, wavelength) and energy.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models; Analyzing and Interpreting Data

Crosscutting Concepts

Patterns; Systems and System Models

Knowledge

Students know:
  • Waves represent repeating quantities.
  • A simple wave has a repeating pattern with a specific wavelength, frequency, and amplitude.
  • The frequency of a wave is the number of waves passing a point in a certain time. The unit of frequency is the hertz (Hz) and one hertz is equal to one wave per second.
  • Amplitude is the maximum displacement of the wave pattern from equilibrium.
  • Wavelength is the distance between consecutive wave crests or troughs.
  • The electromagnetic spectrum is the range of all types of electromagnetic radiation. Radiation is energy that travels and spreads out as it travels.
  • The types of electromagnetic radiation that make up the electromagnetic spectrum are radio waves, visible light, microwaves, infrared light, ultraviolet light, X-rays and gamma-rays.
  • Electromagnetic radiation can be described in terms of a stream of mass-less particles, called photons, each traveling in a wave-like pattern at the speed of light. Each photon contains a certain amount of energy. The different types of radiation are defined by the amount of energy found in the photons. Radio waves have photons with low energies, microwave photons have a little more energy than radio waves, infrared photons have still more, then visible, ultraviolet, X-rays, and, the most energetic of all, gamma-rays.
  • Electromagnetic radiation can be expressed in terms of energy, wavelength, or frequency. Frequency is measured in cycles per second, or Hertz. Wavelength is measured in meters. Energy is measured in electron volts or Joules.

Skills

Students are able to:
  • Develop a model of a simple wave and identify the relevant components.
  • Describe the relationships between components of the model.
  • Use patterns observed from their model to provide causal accounts for events and make predictions for events by constructing explanations.
  • Organize given data to allow for analysis and interpretation of the electromagnetic spectrum.
  • Analyze the data to identify possible causal relationships between waves and their positions in the electromagnetic spectrum.
  • Interpret patterns observed from the data to provide causal accounts for events and make predictions for events by constructing explanations.

Understanding

Students understand that:
  • Relationships exist between wave properties (e.g., frequency, amplitude, wavelength) and energy.
  • These relationships can be predicted and described with models of simple waves.*The electromagnetic spectrum is the range of all types of electromagnetic radiation.
  • Electromagnetic radiation can be expressed in terms of energy, wavelength, or frequency and the types of radiation are arranged in the spectrum based on the measure of their energy, wavelength, and/or frequency.
  • The types of electromagnetic radiation that make up the electromagnetic spectrum are radio waves, visible light, microwaves, infrared light, ultraviolet light, X-rays and gamma-rays.

Vocabulary

  • Manipulate
  • Model
  • Wave
  • Simple wave
  • Predict
  • Wave properties (e.g., frequency, amplitude, wavelength)
  • Energy
  • Analyze
  • Interpret
  • Illustrate
  • Electromagnetic spectrum (radio waves, visible light, microwaves, infrared light, ultraviolet light, X-rays and gamma-rays.
  • Electromagnetic radiation
  • Photons
  • Hertz
  • Volts
  • Joules
  • Displacement

SC15.8.18

Use models to demonstrate how light and sound waves differ in how they are absorbed, reflected, and transmitted through different types of media.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models

Crosscutting Concepts

Structure and Function

Knowledge

Students know:
  • A medium is not required to transmit electromagnetic waves.
  • A sound wave, a type of mechanical wave, needs a medium through which it is transmitted.
  • When a sound wave strikes an object, it is absorbed, reflected, or transmitted depending on the object's material.
  • When a light wave shines on an object, it is absorbed, reflected, or transmitted depending on the object's material and the frequency of the light.
  • The path that light travels can be traced as straight lines, except at surfaces between different transparent materials (e.g., air and water, air and glass) where the path of light bends.
  • The absorption, reflection, and transmission of light and sound waves can be identified by observing relevant characteristics of the wave, such as frequency, amplitude, and wavelength.
  • Materials with certain properties are well-suited for particular functions (e.g., lenses and mirrors, sound absorbers in concert halls, colored light filters, sound barriers next to highways).

Skills

Students are able to:
  • Develop models of light and sound waves and identify the relevant components.
  • Describe the relationships between components of the model.
  • Use observations from the model to provide causal accounts for events and make predictions for events by constructing explanations.

Understanding

Students understand that:
  • Light and sound waves differ in how they interact with different types of media.
  • The absorption, reflection, and transmission of light and sound waves depends on the type of media through which they are transmitted.
  • Materials with certain properties are well-suited for particular functions (e.g., lenses and mirrors, sound absorbers in concert halls, colored light filters, sound barriers next to highways).

Vocabulary

  • Light
  • Sound
  • Absorption
  • Reflection
  • Transmission
  • Media
  • Transparent
  • Translucent
  • Opaque
  • Frequency
  • Amplitude
  • Wavelength
  • Electromagnetic waves

SC15.8.19

Integrate qualitative information to explain that common communication devices (e.g., cellular telephones, radios, remote controls, Wi-Fi components, global positioning systems [GPS], wireless technology components) use electromagnetic waves to encode and transmit information.

Unpacked Content

Scientific and Engineering Practices

Obtaining, Evaluating, and Communicating Information

Crosscutting Concepts

Structure and Function

Knowledge

Students know:
  • Electromagnetic waves are a form of energy waves that have both an electric and magnetic field. Electromagnetic waves are different from mechanical waves in that they can transmit energy and travel through a vacuum.
  • The different types of electromagnetic waves have different uses and functions in our everyday lives.
  • Electromagnetic waves differ from each other in wavelength, frequency, and energy, and are classified accordingly. Wavelength is the distance between one wave crest to the next.
  • Frequency refers to how often the particles of the medium vibrate when a wave passes through the medium
  • The amount of energy carried by a wave is related to the amplitude of the wave. A high energy wave is characterized by a high amplitude; a low energy wave is characterized by a low amplitude. The amplitude of a wave refers to the maximum amount of displacement of a particle on the medium from its rest position.
  • Electromagnetic waves can be used to encode information.
  • Electromagnetic waves can be used to transmit information.
  • Examples of common communication devices may include cellular telephones, radios, remote controls, Wi-Fi components, global positioning systems (GPS), and wireless technology components.

Skills

Students are able to:
  • Gather evidence sufficient to explain a phenomenon that includes the idea that using waves to carry digital signals is a more reliable way to encode and transmit information than using waves to carry analog signals.
  • Combine the relevant information (from multiple sources) to articulate the explanation.

Understanding

Students understand that:
  • Common communication devices use electromagnetic waves to encode and transmit information.

Vocabulary

  • Qualitative
  • Information
  • Communication devices (e.g., cellular phone, Global Positioning System (GPS), remote control, Wi-Fi, etc.)
  • Electromagnetic waves
  • Energy
  • Energy wave
  • Electric field
  • Magnet
  • Magnetic field
  • Mechanical wave
  • Vacuum
  • Frequency
  • Wavelength
  • Crest
  • Medium
  • Amplitude
  • Displacement
  • Rest position
  • Encode
  • Transmit

SC15.BIO.1

Use models to compare and contrast how the structural characteristics of carbohydrates, nucleic acids, proteins, and lipids define their function in organisms.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models

Crosscutting Concepts

Structure and Function

Knowledge

Students know:
  • An atom is composed of smaller particles, such as protons, neutrons and electrons.
  • Atoms of the same or different elements can form chemical bonds. The type of bond formed, such as covalent, ionic, or hydrogen, depends on the atomic structure of the element. Carbohydrates, Lipids, proteins and nucleic acids are the four macromolecules that compose life.
  • Carbohydrates are composed of a monomer of one carbon, 2 hydrogen and one oxygen atoms (CH2O). The role of carbohydrates in biological processes such as photosynthesis and cellular respiration.
  • The role of lipids in biological processes such as cell membrane function and energy storage.
  • The basic structure of a lipid includes fatty acid tails composed of a chain of carbon atoms bonded to hydrogen and other carbon atoms by single or double bonds.
  • Proteins are made of amino acids, which are small compounds that are made of carbon, nitrogen, oxygen hydrogen and sometimes sulfur. The structure of an amino acid consists of a carbon atom in the center which is bonded with a hydrogen, an amino group, a carboxyl group and a variable group—its that variable group that makes each amino acid different.
  • The roles of proteins in biological processes such as enzyme function or structural functionality.
  • Nucleic acids are made of smaller repeating subuntits composed of carbon, nitrogen, oxygen, phosphorus, and hydrogen atoms, called nucleotides.
  • There are six major nucleotides—all of which have three units—a phosphate, a nitrogenous base, and a ribose sugar. The role of nucleic acids in biological processes such as transmission of hereditary information.

Skills

Students are able to:
  • Describe the particles that compose an atom.
  • Relate atomic particles to types of chemical bonding such as covalent, ionic and hydrogen.
  • Describe Van der Waals forces.
  • Identify patterns in the elements that compose each macromolecule.
  • Identify the arrangement of monomer units in carbohydrates, proteins, nucleic acids, and lipids.
  • Differentiate macromolecules based on common characteristics.
  • Construct models of the four major macromolecules.
  • Analyze models of the four major biomolecules to identify the monomer unit that repeats across the macromolecule polymer and relate molecular structure to biological function.

Understanding

Students understand that:
  • Cells are made of atoms.
  • The four macromolecules that compose life are carbohydrates, lipids, nucleic acids, and proteins.
  • Macromolecules contain distinct patterns of monomer subunits that repeat across the macromolecule polymer and that structure affects the biological function of the macromolecule.

Vocabulary

  • Atom
  • Nucleus
  • Proton
  • Neutron
  • Electron
  • Element
  • Compound
  • Isotope
  • Covalent bond
  • Molecule
  • Ion
  • Ionic bond
  • Van der Waals force
  • Macromolecule
  • Polymer
  • Carbohydrate
  • Monosaccharide
  • Disaccharide
  • Polysaccharide
  • Lipid
  • Saturated fats
  • Unsaturated fats
  • Triglyceride
  • Phospholipid
  • Hydrophobic
  • Steroids
  • Protein
  • Amino acid
  • Peptide bonds
  • Nucleic acid
  • Nucleotide
  • DNA
  • RNA
  • ATP

SC15.BIO.2

Obtain, evaluate, and communicate information to describe the function and diversity of organelles and structures in various types of cells (e.g., muscle cells having a large amount of mitochondria, plasmids in bacteria, chloroplasts in plant cells).

Unpacked Content

Scientific and Engineering Practices

Obtaining, Evaluating, and Communicating Information

Crosscutting Concepts

Structure and Function

Knowledge

Students know:
  • Historical contributions to the cell theory by scientists such as Hooke, Leeuwenhoek, Schleiden etc.
  • The cell theory is one of the fundamental ideas of modern biology and includes three principles:
    1. All living things are composed of cells.
    2. Cells are the basic unit of structure and organization of all living organisms.
    3. Cells arise only from previously existing cells.
  • There are many types of organelles.
  • Eukaryotic cells contain a nucleus and other membrane bound organelles.
  • Prokaryotic cells are cells without a nucleus or other membrane bound organelles.
  • How organelles function within a cell.
  • How the function of organelles relates to their presence in various types of cells.
  • The characteristics of different types of cells can be determined based on the presence of certain organelles.

Skills

Students are able to:
  • Obtain information about the function and diversity of organelles and cell structures.
  • Evaluate the function of a cell based on the presence or absence of particular organelles and/or cell structures.
  • Communicate information to describe the function of organelles and cell structures in various types of cells.
  • Communicate information to describe the diversity of organelles and structures in various types of cells.

Understanding

Students understand that:
  • Structures within different types of cells will have different functions.
  • Cellular function is related to the presence and number of particular organelles and cell structures.
  • Various types of cells can be identified by the presence of particular organelles and/or cell structures.

Vocabulary

  • Cell
  • Cell theory
  • Plasma membrane
  • Organelle
  • Cell structures (e.g., cell wall, cell membrane, cytoplasm, etc.)
  • Cell organelles (e.g., nucleus, chloroplast, mitochondrion, etc.)
  • Prokaryote
  • Eukaryote
  • Bacterial cell
  • Plant cell
  • Animal cell
  • Muscle cell
  • Other types of cells such as unicellular organisms (e.g., amoeba), nerve cell, sex cell (sperm/egg), etc.

SC15.BIO.3

Formulate an evidence-based explanation regarding how the composition of deoxyribonucleic acid (DNA) determines the structural organization of proteins.

Unpacked Content

Scientific and Engineering Practices

Engaging in Argument from Evidence; Obtaining, Evaluating, and Communicating Information

Crosscutting Concepts

Patterns

Knowledge

Students know:
  • All living things have DNA How the 5' and 3' orientation of DNA nucleotides results in the antiparallel nature of DNA.
  • The complementary nature of nitrogenous bases.
  • How hydrogen bonding holds complementary bases together across two DNA strands.
  • The basic mechanism of reading and expressing genes is from DNA to RNA to Protein (The Central Dogma of Biology).
  • The first step of the Central dogma is a process called transcription, which synthesizes mRNA from DNA.
  • The process where the mRNA connects to a ribosome, the code is read and then translated into a protein is called translation.
  • To become a functional protein, a translated chain of amino acids must be folded into a specific three-dimensional shape.
  • Historically important experiments that led to the development of the structure of DNA, including Mieshcer, Chargraff, Rosalind Franklin, Watson/Crick, etc.
  • DNA changes can be linked to observable traits in the natural world, such as diseases.
  • Common laboratory techniques are used to obtain evidence that supports the premise that DNA changes may affect proteins and in turn the appearance of traits.
  • Types of errors that can occur during replication and the impact these errors have on protein production and/or function.

Skills

Students are able to:
  • Build from scratch or work with previously constructed models of DNA to identify the key structural components of the molecule.
  • Obtain and communicate information (possibly through a conceptual model) describing how information encoded in DNA leaves the nucleus.
  • Obtain and expand explanation to include how the information transcribed from DNA to RNA determines the amino acid sequence of proteins.
  • Identify and describe the function of molecules required for replication and differentiate between replication on the leading and lagging DNA strands.
  • Group mRNA into codons and identify the amino acid associated with each codon. Create and manipulate polypeptide models to demonstrate protein folding.
  • Use a variety of resources (web-based timelines, original publications, documentaries, and interviews), explain how historically important experiments helped scientists determine the molecular structure of DNA, and develop the concept of the Central Dogma of Biology.
  • Analyze a variety of diagnostic techniques that identify genetic variation in a clinical setting.
  • Relate protein structure to enzyme function and discuss the causes and impacts of protein denaturation on both enzymes and structural proteins.
  • Identify the impact of DNA changes on the structure and/or function of the resulting amino acid sequences.
  • Predict the impact of errors during DNA replication in terms of protein production and/or function.
  • Classify types of DNA changes (deletions, insertions, and substitutions).
  • Use models to explain how deletions, insertions, translocation, substitution, inversion, frameshift, and point mutations occur during the process of DNA replication.

Understanding

Students understand that:
  • The traits of living things are ultimately determined by inherited sequences of DNA.
  • The end product of transcription is always RNA, but the process produces many different types of RNA with varying functions.
  • DNA instructions are replicated and passed from parent to offspring, segregating traits across generations in a mathematically predictable manner.
  • A protein is a linear sequence of amino acids that spontaneously folds following rules of chemistry and physics.
  • A series of historically important experiments let to the current understanding of the structure of DNA and the Central Dogma of Biology.
  • Errors that occur during DNA replication can affect protein production and/or function. Important projects over the past 30 years have changed the definition of a "gene" and increased the ability to assess the impact of DNA variation in a trait or disease.
  • Genetic change can lead to altered protein function and the appearance of a different trait or disease.

Vocabulary

  • Nitrogenous bases
  • Deoxyribose
  • Phosphates
  • Hydrogen bonding
  • Nucleotides
  • Semi-conservative replication
  • Central Dogma
  • Transcription
  • Various types of RNA, including those involved in protein synthesis (mRNA, tRNA & rRNA) and those associated with gene regulation (e.g., IncRNA, miRNA, siRNA) and post-transcriptional modification (snRNA)
  • RNA polymerase
  • Introns
  • Exons
  • Codon
  • Translation
  • Anticodon
  • Deletion
  • Insertion
  • Substitution
  • Variant
  • DNA sequencing
  • PCR
  • Gel electrophoresis
  • Big Science Projects conducted over last 30 years: Human Genome Project, The International Hap Map, ENCODE, Cancer Genome Atlas, 1000 Genomes project, ClinVar and ClinGen, and the Exome Aggregation
  • Consortium.
  • Deletion
  • Insertion
  • Translocation
  • Substitution
  • Inversion
  • Frameshift mutations
  • Point mutations

SC15.BIO.3a

Obtain and evaluate experiments of major scientists and communicate their contributions to the development of the structure of DNA and to the development of the central dogma of molecular biology.

SC15.BIO.3b

Obtain, evaluate, and communicate information that explains how advancements in genetic technology (e.g., Human Genome Project, Encyclopedia of DNA Elements [ENCODE] project, 1000 Genomes Project) have contributed to the understanding as to how a genetic change at the DNA level may affect proteins and, in turn, influence the appearance of traits.

SC15.BIO.3c

Obtain information to identify errors that occur during DNA replication (e.g., deletion, insertion, translocation, substitution, inversion, frame-shift, point mutations).

SC15.BIO.4

Develop and use models to explain the role of the cell cycle during growth and maintenance in multicellular organisms (e.g., normal growth and/or uncontrolled growth resulting in tumors).

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models

Crosscutting Concepts

Systems and System Models

Knowledge

Students know:
  • The phases of the cell cycle (Interphase-G1, S, and G2 phases, Mitosis and cytokenisis), the amount of time spent in each cycle and what occurs during each cycle.
  • The process of cell cycle regulation.
  • Mechanisms, checkpoints and signaling factor molecules that regulate the cell cycle.

Skills

Students are able to:
  • Generate a graphic illustrating the amount of time a cell spends in each phase of the cell cycle.
  • Observe video, image or microscope slide and identify cells in each phase, relative abundance, and estimate the time spent in each phase.
  • Obtain and communicate information about the relationship between the cell cycle and the growth and maintenance of an organism.
  • Illustrate chromosome behavior during mitosis using chromosome models.
  • Distinguish between replicated and un-replicated chromosomes.
  • Demonstrate the events and cellular processes involved in each stage of mitosis.
  • Investigate the impact of errors in the process of cell division.
  • Identify the basic mechanisms, checkpoints, and general categories of signaling factor molecules (both internal and external).
  • Relate errors in control mechanisms to uncontrolled cell growth (cancer).

Understanding

Students understand that:
  • The cell cycle is necessary for growth and maintenance in multi-cellular organisms.
  • Mitosis only makes somatic (body) cells.
  • Errors in control mechanisms within the cell cycle lead to uncontrolled cell growth (cancer).

Vocabulary

  • Cell cycle
  • Chromosome
  • Somatic cell
  • Chromatin
  • Spindle fibers
  • Kinetochore microtubules
  • Centrioles
  • Centrosome
  • Centromere
  • Sister chromatids
  • Mitosis
  • Prometaphase
  • Prophase
  • Metaphase
  • Metaphase plate
  • Anaphase
  • Telophase
  • Cytokinesis
  • Cell plate
  • Cleavage furrow
  • Interphase
  • S phase
  • G1
  • G2
  • Growth
  • Maintenance
  • Checkpoints
  • Signaling factors

SC15.BIO.5

Plan and carry out investigations to explain feedback mechanisms (e.g., sweating and shivering) and cellular processes (e.g., active and passive transport) that maintain homeostasis.

Unpacked Content

Scientific and Engineering Practices

Planning and Carrying out Investigations

Crosscutting Concepts

Structure and Function; Stability and Change

Knowledge

Students know:
  • A negative feedback loop is when the body senses (receptor) an internal change (stimulus) and activates mechanisms (effector) that reverse, or negate (response) that change (e.g., Regulation of body temperature).
  • The positive feedback loop is a process where the body senses a change and activates mechanisms that accelerate or increase that change—can aid in homeostasis but also can be life threatening (e.g., blood clotting (helpful), response to myocardial infarction (potentially fatal).
  • The chemical structure of the phospholipid membrane and the various ways large and small molecules move between the inside and outside of the cell to maintain homeostasis.
  • The movement of water is a cellular response to different solute concentrations within and outside the cell.

Skills

Students are able to:
  • Investigate and communicate factors that affect homeostasis in living organisms.
  • Develop an answerable scientific question and plan and carry out an investigation that provides data about homeostasis.
  • Investigate the function of the plasma membrane in relation to cellular processes that maintain homeostasis within the cell.
  • Observe and explore simple experiments to develop a working list of the properties of water.
  • Use a model to explain the properties of water at a molecular level.
  • Use a model to illustrate chemical interactions between water molecules and other polar and non-polar compounds.
  • Design an experiment that provides data regarding one property of water and communicate the experimental design, results and conclusions.

Understanding

Students understand that:
  • Homeostasis is the tendency of an organism or cell to regulate its internal environment and maintain equilibrium, usually by a system of feedback controls, so as to stabilize health and functioning.
  • A complex set of chemical, thermal and neural factors interact in complex ways, both helping and hindering the body while it works to maintain homeostasis.
  • Water movement is critical to the maintenance of homeostasis for cells and vascular systems.

Vocabulary

  • Negative feedback loop
  • Positive feedback
  • Enzyme related feedback
  • Stimulus
  • Response
  • Effector
  • Receptor
  • Afferent pathway
  • Efferent pathway
  • Integration
  • Phospholipid bilayer
  • Selective permeability
  • Transport protein
  • Fluid mosaic model
  • Polarity
  • Surface tension
  • Capillary
  • Adhesion
  • Cohesion
  • Hypotonic
  • Hypertonic
  • Isotonic
  • Active transport
  • Passive transport
  • Mixture
  • Solution
  • Solvent
  • Solute
  • Diffusion
  • Dynamic equilibrium
  • Facilitated diffusion
  • Osmosis
  • Endocytosis
  • Exocytosis

SC15.BIO.5a

Plan and carry out investigations to explain how the unique properties of water (e.g., polarity, cohesion, adhesion) are vital to maintaining homeostasis in organisms.

SC15.BIO.6

Analyze and interpret data from investigations to explain the role of products and reactants of photosynthesis and cellular respiration in the cycling of matter and the flow of energy.

Unpacked Content

Scientific and Engineering Practices

Planning and Carrying out Investigations; Analyzing and Interpreting Data

Crosscutting Concepts

Cause and Effect; Energy and Matter

Knowledge

Students know:
  • Autotrophs obtain energy directly from sunlight.
  • Heterotrophs obtain energy by eating autotrophs and other heterotrophs.
  • The relationship between CO2 and O2 in photosynthesis and respiration—recognize that the reactants of one are the products of the other.
  • The inputs and outputs of energy at each stage of photosynthesis—stage I, the light-dependent reactions and stage II, the light-independent reactions (Calvin Cycle).
  • The structure and function of ATP--Energy is stored in the bonds between phosphates in ATP and released when those bonds are broken.
  • The inputs and outputs of energy at each stage of Cellular respiration—Glycolysis, the Krebs cycle and Electron transport.
  • The role of plant pigments in photosynthesis.
  • The red and blue ends of the visible part of the electromagnetic spectrum are used by plants in photosynthesis while the reflection and transmission of the middle of the spectrum gives leaves their green visual color (in most cases).

Skills

Students are able to:
  • Formulate a scientific question about how energy is stored and/or released in living systems.
  • Analyze information about how photosynthesis converts light energy into stored chemical energy.
  • Interpret data illustrating the relationship between photosynthesis and cellular respiration.
  • Explain the relationship between photosynthesis and cellular respiration in terms of energy flow and cycling of matter.
  • Investigate the relationship between wavelength and energy.
  • Investigate the energy absorbed and reflected by photosynthetic pigments at specific wavelengths.
  • Interpret data describing the absorption and reflection of wavelengths by various pigments.
  • Describe the relationship between pigments, wavelength and energy.

Understanding

Students understand that:
  • Photosynthesis and cellular respiration are two important processes that cells use to obtain energy.
  • The products of photosynthesis are oxygen and glucose, the reactants needed for cellular respiration.
  • The products of cellular respiration, carbon dioxide and water, are the reactants needed for photosynthesis.
  • Photosynthesis is dependent on the absorption of light by pigments in the leaves of plants.

Vocabulary

  • Energy
  • Thermodynamics
  • Metabolism
  • Photosynthesis
  • Cellular respiration
  • Adenosine triphosphate (ATP)
  • Autotroph
  • Heterotroph
  • Chloroplasts
  • chlorophylls
  • Thylakoid
  • Granum
  • Stroma
  • Pigment
  • Photosystems I & II
  • NADP+
  • NADPH
  • chemiosmosis
  • Calvin Cycle
  • Rubisco
  • Anaerobic process
  • Aerobic respiration
  • Aerobic process
  • Glycolysis
  • ATP
  • Pyruvate
  • Krebs cycle
  • Fermentation (lactic acid and alcohol)

SC15.BIO.7

Develop and use models to illustrate examples of ecological hierarchy levels, including biosphere, biome, ecosystem, community, population, and organism.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models

Crosscutting Concepts

Systems and System Models

Knowledge

Students know:
  • The biosphere is the portion of the Earth that supports life.
  • The lowest level of organization is the individual organism itself.
  • Individual organisms of a single species that share the same geographical location at the same time make up the population.
  • A group of interacting populations that occupy the same geographical area at the same time is a biological community.
  • An ecosystem is the biological community and all the abiotic factors that affect it (e.g., water temperature, light availability).
  • A biome is a large group of ecosystems that share the same climate and have similar types of communities.

Skills

Students are able to:
  • Organize objects or organisms into levels of hierarchy.
  • Develop a hierarchical classification model using standard language and parameters.

Understanding

Students understand that:
  • In order to study relationships within the biosphere, it is divided into smaller levels of organization.
  • The simplest level of organization is the organism, with increasing levels of complexity as the numbers and interactions between organisms increase, shown in the population, biological community, ecosystem, and biome until reaching the most complex level of the biosphere.

Vocabulary

  • Ecology
  • Biosphere
  • Biotic factor
  • Abiotic factor
  • Population
  • Biological community
  • Ecosystem
  • Biome
  • Species

SC15.BIO.8

Develop and use models to describe the cycling of matter (e.g., carbon, nitrogen, water) and flow of energy (e.g., food chains, food webs, biomass pyramids, ten percent law) between abiotic and biotic factors in ecosystems.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models

Crosscutting Concepts

Systems and System Models; Energy and Matter

Knowledge

Students know:
  • A food chain is a simple model representing the transfer of energy from organism to organism (e.g., sun → plant → grasshopper → mouse → snake).
  • Each step of a food chain represents a trophic level always starting with an autotroph in the first level and heterotrophs in the remaining levels.
  • The overlapping relationships between multiple food chains are shown in a food web.
  • An ecological pyramid is a model that can show the relative amounts of energy, biomass, or numbers of organisms at each trophic level in an ecosystem.
  • In an energy pyramid, only 10% of energy is passed from one trophic level to the next due to loss of energy in the form of heat caused by cellular respiration (10% rule).
  • In a biomass pyramid, the total mass of living matter at each trophic level tends to decrease.
  • In a numbers pyramid, it shows the number of organisms at each trophic level tends to decrease because there is less energy available to support organisms.
  • The exchange of matter through the biosphere is called the biogeochemical cycle and involves living organisms (bio), geological processes (geo), and chemical processes (chemical).

Skills

Students are able to:
  • Use a self-created food web diagram to predict the impact of removing one organism on other organisms within the food web.
  • Use data to create ecological pyramids to show flow of energy, biomass and number of organisms.
  • Model the cycling of matter (e.g., Carbon, water, nitrogen) through the biosphere.
  • Combine a food web diagram with a matter cycling diagram to provide a holistic view of the many aspects that make up an ecosystem.

Understanding

Students understand that:
  • Everything in an ecosystem is connected to everything else (both abiotic and biotic), either directly or indirectly.
  • Nutrients, in the form of elements and compounds, flow through organisms in an ecosystem (e.g., grass captures substances from the air, soil and water and converts them into usable nutrients → cow eats the grass → human eats the cow → decomposers return the nutrients to the cycle at every level).

Vocabulary

  • Autotroph
  • Heterotroph
  • Primary producer
  • Primary consumer
  • Secondary consumer
  • Tertiary consumer
  • Herbivore
  • Carnivore
  • Omnivore
  • Detritivore
  • Trophic levels: primary, secondary and tertiary
  • Food chain
  • Food web
  • Biomass
  • Energy pyramid
  • Biomass pyramid
  • Number pyramid
  • Matter
  • Nutrient
  • Biogeochemical cycle
  • Nitrogen fixation
  • Denitrification
  • Law of conservation of mass

SC15.BIO.9

Use mathematical comparisons and visual representations to support or refute explanations of factors that affect population growth (e.g., exponential, linear, logistic).

Unpacked Content

Scientific and Engineering Practices

Using Mathematics and Computational Thinking

Crosscutting Concepts

Scale, Proportion, and Quantity

Knowledge

Students know:
  • Exponential population growth occurs when the growth rate is proportional to the size of the population (J shaped curve).
  • Logistic population growth shows the population leveling off when it reaches carrying capacity (S shaped curve).
  • Linear population growth is the addition of the same number of organisms to the population at a constant rate, no matter the size of the population (strait line growth).
  • Environmental factors (density-independent factors) that can impact population growth (flood, drought, extreme heat or cold, etc.).
  • Ecological factors (density-dependent) that can affect population growth (e.g., predation, disease, parasites, competition).

Skills

Students are able to:
  • Use data to create graphs.
  • Calculate doubling time for a population.
  • Mathematically compare populations experiencing varying conditions.
  • Investigate various factors (both environmental and ecological) that impact population growth.
  • Draw conclusions from population growth graphs.
  • Using various visual representations of data, make claims about specific causes and effects.

Understanding

Students understand that:
  • An important characteristic of any population is its growth rate.
  • Some populations remain approximately the same size from year to year while others vary in size depending on conditions within their habitats.
  • Populations tend to stabilize near the carrying capacity of their environment.

Vocabulary

  • Population growth rate
  • Emigration
  • Immigration
  • Exponential, linear and logistic growth
  • Doubling time
  • Carrying capacity
  • Density-independent
  • Density-dependent

SC15.BIO.10

Construct an explanation and design a real-world solution to address changing conditions and ecological succession caused by density-dependent and/or density-independent factors.*

Unpacked Content

Scientific and Engineering Practices

Constructing Explanations and Designing Solutions

Crosscutting Concepts

Cause and Effect

Knowledge

Students know:
  • Factors associated with population density are important regulators of population growth.
  • Density-independent factors that can impact population growth (e.g., flood, drought, extreme heat or cold, tornadoes, etc.).
  • Density-dependent factors that can impact population growth (e.g., predation, disease, parasites, competition).
  • The different types of ecological succession and their causes. Primary succession is the development of a community in an area of exposed rock that does not have any topsoil (e.g., hardened lava flow).
  • Secondary Succession is the change that takes place after a community of organisms have been removed but the topsoil remains intact (e.g., fire, flood, etc.).
  • Engineering design principles.

Skills

Students are able to:
  • Collect and organize population growth data compiled on population growth under varying conditions related to food availability, rainfall, predation, migration, and disease.
  • Analyze data to categorize factors, organize data and draw conclusions about a variety of limiting factors to classify each as density-dependent or independent.
  • Identify a problem, assess the data, determine if enough information is provided to make an informed decision, assess whether a solution is needed, and recommend what form that solution should take.
  • Apply engineering design principles to the development of a solution, identifying required inputs and expected outcomes and determine how the solution will be tested and refined.

Understanding

Students understand that:
  • Ecosystems are constantly changing.
  • Changes in an ecosystem are the result of density-dependent or density-independent factors, sometimes including human activity.
  • By using the engineering design process, solutions to ecological problems can be developed, tested and refined.

Vocabulary

  • Population density
  • Dispersion
  • Density-independent factor
  • Density-dependent factor
  • Population growth rate
  • Limiting factor
  • Ecological succession
  • Primary succession
  • Climax community
  • Secondary succession
  • Pioneer species

SC15.BIO.11

Analyze and interpret data collected from probability calculations to explain the variation of expressed traits within a population.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models; Analyzing and Interpreting Data; Using Mathematics and Computational Thinking

Crosscutting Concepts

Patterns; Systems and System Models

Knowledge

Students know:
  • Inheritable genetic variations may result from: new genetic combinations through meiosis, viable errors occurring during replication, and mutations caused by environmental factors.
  • Variations in genetic material naturally result during meiosis when corresponding sections of chromosome pairs exchange places.
  • Genetic material is inheritable.
  • Genetic variations produced by mutations and meiosis are inheritable.
  • The difference between genotypic and phenotypic ratios and percentages.
  • Examples of genetic crosses that do not fit traditional inheritance patterns (e.g., incomplete dominance, co-dominance, multi-allelic, polygenic) and explanations as to how the observed phenotypes are produced.
  • Mendel's laws of segregation and independent assortment.
  • Pedigrees can be used to infer genotypes from the observation of genotypes.
  • By analyzing a person's family history or a population study, disorders in future offspring can be predicted.

Skills

Students are able to:
  • Perform and use appropriate statistical analysis of data, including probability measures to determine the relationship between a trait's occurrence within a population and environmental factors.
  • Differentiate between homozygous and heterozygous allele pairings.
  • Create Punnett squares to predict offspring genotypic and phenotypic ratios.
  • Explain the relationship between the inherited genotype and the visible trait phenotype.
  • Examine genetic crosses that do not fit traditional inheritance patterns (incomplete dominance and co-dominance).
  • Use chromosome models to physically demonstrate the points in meiosis where Mendel's laws of segregation and independent assortment are observed.
  • Analyze pedigrees to identify the patterns of inheritance for specific traits/ disorders including autosomal dominant/ recessive as well as sex-linked and mitochondrial patterns.

Understanding

Students understand that:
  • In sexual reproduction, chromosomes can sometimes swap sections during the process of meiosis, thereby creating new genetic combinations and thus more genetic variation.
  • Although DNA replication is tightly regulated and remarkably accurate, errors do occur and result in mutations, which are also a source of genetic variation.
  • Environmental factors can also cause mutations in genes, and viable mutations are inherited.
  • Environmental factors also affect expression of traits, and hence affect the probability of occurrences of traits in a population.
  • The variation and distribution of traits observed depends on both genetic and environmental factors.

Vocabulary

  • Genetics
  • Allele
  • Dominant
  • Recessive
  • Homozygous
  • Heterozygous
  • Genotype
  • Phenotype
  • Law of segregation
  • Hybrid
  • Law of independent assortment
  • F1 and F2 generations
  • Monohybrid
  • Dihybrid
  • Punnet square
  • Probability
  • Crossing over
  • Genetic recombination
  • Carrier
  • Pedigree
  • Incomplete dominance
  • Codominance
  • Multiple alleles
  • Epistasis
  • Sex chromosome
  • Autosome
  • Sex-linked trait
  • Polygenic trait

SC15.BIO.11a

Use mathematics and computation to predict phenotypic and genotypic ratios and percentages by constructing Punnett squares, including using both homozygous and heterozygous allele pairs.

SC15.BIO.11c

Analyze and interpret data (e.g., pedigree charts, family and population studies) regarding Mendelian and complex genetic disorders (e.g., sickle-cell anemia, cystic fibrosis, type 2 diabetes) to determine patterns of genetic inheritance and disease risks from both genetic and environmental factors.

SC15.BIO.12

Develop and use a model to analyze the structure of chromosomes and how new genetic combinations occur through the process of meiosis.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models; Analyzing and Interpreting Data

Crosscutting Concepts

Patterns; Systems and System Models

Knowledge

Students know:
  • Chromosomes appearing as an "X" shape are replicated chromosomes consisting of two sister chromatids.
  • The difference between mitosis and meiosis in terms of chromosome number and number of daughter cells produced.
  • Crossing over is where chromosomal segments are exchanged when homologous chromosomes are lined up during Prophase I.
  • Crossing over leads to more genetic variation within the population.
  • Types of errors that can occur during meiosis that can lead to genetic disorders such as nondisjunction where chromosomes fail to separate properly during Meiosis I or II and result in gametes not having the proper number of chromosomes or in disorders caused by breakage and improper rejoining of chromosome broken ends such as in deletions, insertions, inversions and translocations.

Skills

Students are able to:
  • Develop models of replicated and non-replicated chromosomes and identify important parts of their structure.
  • Compare diagrams of mitosis and meiosis and list the differences between the two.
  • Develop a model of chromosome movement at each stage of meiosis.
  • Determine whether a cell is haploid or diploid.
  • Evaluate meiosis models, comparing them to the biological process, and identify strengths and weaknesses of the model.
  • Interpret human karyotypes to identify typical chromosome patterns as well as various large-scale chromosome errors.

Understanding

Students understand that:
  • In sexual reproduction, chromosomes can sometimes swap sections during the process of meiosis, thereby creating new genetic combinations and thus more genetic variation.
  • Errors can occur during meiosis which can lead to genetic disorders.

Vocabulary

  • Chromosome
  • Replicated chromosome
  • Sister chromatids
  • Telomeres
  • Centromere
  • Homologous chromosome pairs
  • Haploid (n)
  • Diploid (2n)
  • Gene
  • Gamete
  • Fertilization
  • Meiosis
  • Crossing over
  • Meiosis I
  • Interphase
  • Prophase I
  • Metaphase I
  • Anaphase I
  • Telophase I
  • Meiosis II
  • Prophase II
  • Metaphase II
  • Anaphase II
  • Telophase II
  • Cytokinesis
  • Karyotype
  • Nondisjunction

SC15.BIO.13

Obtain, evaluate, and communicate information to explain how organisms are classified by physical characteristics, organized into levels of taxonomy, and identified by binomial nomenclature (e.g., taxonomic classification, dichotomous keys).

Unpacked Content

Scientific and Engineering Practices

Engaging in Argument from Evidence; Obtaining, Evaluating, and Communicating Information

Crosscutting Concepts

Patterns

Knowledge

Students know:
  • Historical systems of classification (Aristotle, Linnaeus).
  • Taxa are organized into a hierarchal system—each taxa contained within another, arranged from broadest to most specific.(domain ← kingdom ← phylum ← class ← order ← family ← genus ← species)
  • Characteristics of living things: made of cells, obtain and use energy, grow and develop, reproduce, respond to their environment, adapt to their environment.
  • Viruses do not exhibit all the characteristics of life: they do not possess cells, nor are they cells, they have no organelles to take in nutrients or use energy, they cannot make proteins, they cannot move, and they cannot replicate on their own.

Skills

Students are able to:
  • Organize items based on physical characteristics and/or DNA sequences, etc. and communicate reasoning to others.
  • Design a classification scheme (e.g., dichotomous key) for a collection of common but not necessarily related objects.
  • Correctly write an organism's name using binomial nomenclature.
  • Research viruses using a variety of sources—analysis should include viral life cycles, reproductive strategies and their structure and function.
  • Argue from evidence whether a virus is living or not.

Understanding

Students understand that:
  • Biologists find it easier to communicate and retain information about organisms when organisms are organized into groups.
  • Though viruses exhibit several of the characteristics of life, they are not considered to be living things and are not included in the biological classification system.

Vocabulary

  • Classification
  • Taxonomy
  • Binomial nomenclature
  • Taxon
  • Genus
  • Family
  • Order
  • Class
  • Phylum
  • Division
  • Kingdom
  • Domain
  • Dichotomous key
  • Virus
  • Capsid
  • Lytic cycle
  • Lysogenic cycle
  • Retrovirus
  • Prion

SC15.BIO.14

Analyze and interpret data to evaluate adaptations resulting from natural and artificial selection that may cause changes in populations over time (e.g., antibiotic-resistant bacteria, beak types, peppered moths, pest-resistant crops).

Unpacked Content

Scientific and Engineering Practices

Analyzing and Interpreting Data

Crosscutting Concepts

Cause and Effect

Knowledge

Students know:
  • Organisms can produce enormous numbers of offspring.
  • These offspring must compete for limited resources.
  • These offspring also have genetic differences that are observed as phenotypic trait variations.
  • The offspring whose phenotypes provide the best chance to survive to adulthood and reproduce will pass on the highest frequency of their traits (and therefore genetic differences) to the next generation.
  • The process of directed breeding to produce offspring with desired traits is called selective breeding or artificial selection.

Skills

Students are able to:
  • Analyze and interpret data to recognize a pattern in changes in populations over time.
  • Analyze different sources of evidence.
  • Interpret the validity of data.
  • Read and construct a graph.
  • Recognize examples of artificial selection.
  • Predict phenotypic adaptations as a result of changing environments.
  • Compare organisms derived from artificial selection with their wild ancestors, who were products of natural selection.

Understanding

Students understand that:
  • Natural selection leads to adaptation—to a population dominated by organisms that are anatomically, behaviorally, and physiologically well suited to survive and reproduce in a specific environment.
  • Survival and reproduction of organisms that have an advantageous heritable trait leads to an increase in the proportion of individuals in future generations that have the trait and to a decrease in the proportion of individuals that do not.
  • The distribution of traits in a population can change when conditions change.
  • Artificial selection allows humans to produce plants or animals with desired traits.

Vocabulary

  • Artificial selection
  • Natural selection
  • Evolution
  • Genetic variation
  • Geographic variation
  • Mutation
  • Evolutionary fitness
  • Phenotypes
  • Genotypes
  • Sexual reproduction
  • Adaptations
  • Artificial selection
  • Genetic isolation
  • Adaptive radiation

SC15.BIO.15

Engage in argument from evidence (e.g., mathematical models such as distribution graphs) to explain how the diversity of organisms is affected by overpopulation of species, variation due to genetic mutations, and competition for limited resources.

Unpacked Content

Scientific and Engineering Practices

Engaging in Argument from Evidence

Crosscutting Concepts

Cause and Effect

Knowledge

Students know:
  • As species grow in number, competition for limited resources can arise.
  • Individuals in a species have genetic variation (through mutations and sexual reproduction) that is passed on to their offspring.
  • Genetic variation can lead to variation of expressed traits in individuals in a population.
  • Individuals can have specific traits that give them a competitive advantage relative to other individuals in the species.
  • Individuals that survive and reproduce at a higher rate will provide their specific genetic variations to a greater proportion of individuals in the next generation.
  • Over many generations, groups of individuals with particular traits that enable them to survive and reproduce in distinct environments using distinct resources can evolve into a different species.
  • Natural selection is a process while biological evolution can result from that process.

Skills

Students are able to:
  • Identify examples of adaptations among various organisms that increase fitness—camouflage, mimicry, drought tolerance, defensive coloration, beak adaptations.
  • Use reasoning to connect the evidence to construct an argument.
  • Interpret data.
  • Defend a position.
  • Use evidence to correlate claims about cause and effect.

Understanding

Students understand that:
  • Natural selection occurs only if there is both variation in the genetic information between organisms in a population and variation in the expression of that genetic information (trait variation) that leads to differences in performance among individuals.
  • Evolution is the consequence of the interaction of four factors:
    1. The potential for a species to increase in number.
    2. The genetic variation of individuals in a species due to mutation and sexual reproduction.
    3. Competition for an environment's limited supply of the resources that individuals need in order to survive and reproduce.
    4. The ensuing proliferation of those organisms that are better able to survive and reproduce in the environment.

Vocabulary

  • Variation
  • Adaptation
  • Fitness
  • Biodiversity
  • Habitat
  • Ecosystems
  • Diversity
  • Population
  • Population density
  • Limiting factors
  • Carrying capacity
  • Genetic mutation
  • Competition
  • Natural selection
  • Genetic recombination

SC15.BIO.16

Analyze scientific evidence (e.g., DNA, fossil records, cladograms, biogeography) to support hypotheses of common ancestry and biological evolution.

Unpacked Content

Scientific and Engineering Practices

Obtaining, Evaluating, and Communicating Information

Crosscutting Concepts

Patterns

Knowledge

Students know:
  • Common ancestry and biological evolution are supported by multiple lines of empirical evidence including:
    1. Information derived from DNA sequences.
    2. Similarities of the patterns of amino acid sequences.
    3. Patterns in the fossil record.
    4. Pattern of anatomical and embryological similarities.

Skills

Students are able to:
  • Examine historical explanations for the diversity of life on earth, including the work of Lamarck, Wallace, and Darwin.
  • Analyze parasitic, mutualistic and commensalistic relationships to investigate large scale evolutionary strategies such as coevolution, convergent evolution and divergent evolution.
  • Analyze fossil records, comparing the structure of extinct to existing species of living things.
  • Analyze DNA or amino acid sequences of closely related and distantly related organisms.
  • Construct a cladogram or phylogenetic tree using molecular sequences and fossil records.
  • Compare and contrast vestigial and homologous structures in modern organisms.

Understanding

Students understand that:
  • Genetic information, like the fossil record, provides evidence of evolution. DNA sequences vary among species, but there are many overlaps—multiple lines of descent can be inferred by comparing the DNA sequences of different organisms.
  • There are multiple lines of empirical evidence that support biological evolution.

Vocabulary

  • Biogeography
  • Parasitism
  • Mutualism
  • Commensalism
  • Co-evolution
  • convergent evolution
  • divergent
  • cladogram
  • phylogenetic tree
  • vestigial structures
  • homologous structures
  • embryonic
  • genetic conservation

SC15.CHM.1

Obtain and communicate information from historical experiments (e.g., work by Mendeleev and Moseley, Rutherford’s gold foil experiment, Thomson’s cathode ray experiment, Millikan’s oil drop experiment, Bohr’s interpretation of bright line spectra) to determine the structure and function of an atom and to analyze the patterns represented in the periodic table.

Unpacked Content

Scientific and Engineering Practices

Obtaining, Evaluating, and Communicating Information

Crosscutting Concepts

Structure and Function

Knowledge

Students know:
  • Examples of scientists and scientific discoveries that changed our knowledge of atomic structure.
  • How these scientific discoveries relate to the information found on the periodic table.
  • Each atom has a charged substructure that consists of a nucleus, which is made of protons and neutrons, surrounded by electrons.
  • The periodic table orders elements horizontally by the number of protons in the atom's nucleus and places those with similar properties in columns.

Skills

Students are able to:
  • Obtain information from multiple, grade-level appropriate materials (text, media, visual displays, data).
  • Communicate information from a variety of reliable sources in multiple formats (oral, graphical, textual, and/or mathematical).

Understanding

Students understand that:
  • It is important to gather, read, and synthesize information from multiple appropriate sources and assess the credibility, accuracy, and possible bias of each publication and methods used.
  • Our knowledge of the structure and function of the atom changed over time due to scientific discoveries, and the history of the periodic table traces our understanding of the atom.
  • Macroscopic patterns are related to the nature of atomic/ molecular/ particulate level structure.

Vocabulary

  • Atomic theory
  • Periodic table history
  • Macroscopic level
  • Atomic/ molecular/ particulate level

SC15.CHM.2

Develop and use models of atomic nuclei to explain why the abundance-weighted average of isotopes of an element yields the published atomic mass.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models

Crosscutting Concepts

Scale, Proportion, and Quantity

Knowledge

Students know:
  • Each atom has a charge substructure that consists of a nucleus, which is made of protons and neutrons, surrounded by electrons.
  • The majority of an atom's mass comes from the protons and neutrons in the nucleus.
  • Electrons have a very small mass, so they are not typically included in atomic mass calculations.
  • Atoms of an element can have different masses, and we call those atoms isotopes.
  • Isotopes of a given element have the same number of protons, but different number of neutrons.
  • Most elements exist in nature in isotopic form.

Skills

Students are able to:
  • Develop a model based on evidence to illustrate the relationship between the structure of the atom and the average atomic mass of an element.
  • Use the model to make predictions.
  • Calculate weighted averages.
  • Determine the most common isotopic form of an element in nature.

Understanding

Students understand that:
  • Models can be computational or mathematical.
  • The published atomic mass of an element is a weighted average of all known isotopes of that element.
  • Macroscopic patterns are related to the nature of atomic/ molecular/ particulate level structure.

Vocabulary

  • Atomic mass
  • Isotopes
  • Abundance
  • Weighted average
  • Nucleus
  • Protons
  • Neutrons
  • Macroscopic level
  • Atomic/ molecular/ particulate level

SC15.CHM.3

Use the periodic table as a systematic representation to predict properties of elements based on their valence electron arrangement.

Unpacked Content

Scientific and Engineering Practices

Developing and Using Models; Analyzing and Interpreting Data

Crosscutting Concepts

Patterns; Systems and System Models; Structure and Function

Knowledge

Students know:
  • The atom has a positively-charged nucleus, containing protons and neutrons, surrounded by negatively-charged electrons.
  • The periodic table can be used to determine the number of particles in an atom of a given element.
  • The relationship between the arrangement of main group elements on the periodic table and the pattern of valence electrons in their atoms.
  • The relationship between the arrangement of elements on the periodic table and the number of protons in their atoms.
  • The trends in relative size, reactivity, and electronegativity in atoms are based on attractions of the valence electrons to the nucleus.
  • The number and types of bonds formed (i.e. ionic, covalent, metallic) by an element and between elements are based on the arrangement of valence electrons in the atoms.
  • The shapes of molecules are based on the arrangement of valence electrons in the atoms.
  • The rules for naming chemical compounds are based upon the type of bond formed.
  • The number and charges in stable ions that form from atoms in a group of the periodic table are based on the arrangement of valence electrons in the atoms.

Skills

Students are able to:
  • Predict relative properties of elements using the periodic table.
  • Predict patterns in periodic trends based on the structure of the atom.
  • Predict patterns in bonding and shape based on the structure of the atom.
  • Use the periodic table to determine how elements will bond.

Understanding

Students understand that:
  • Models are based on evidence to illustrate the relationships between systems or between components of a system.
  • Each atom has a charged substructure consisting of a nucleus, which is made of protons and neutrons, surrounded by electrons.
  • The periodic table arranges elements into periods/ rows by the number of protons in the atom's nucleus.
  • Elements with similar properties are placed into groups/ families/ columns based on the repeating pattern of valence electrons in their atoms.
  • Attraction and repulsion between electrical charges at the atomic scale explain the structure, properites, and transformations of matter, as well as the contact forces between material objects.
  • The attraction and repulsion of charged particles in the atom creates patterns of properties of elements.
  • The arrangement of valence electrons in an atom also creates patterns of properties of elements.
  • Elements form bonds based upon their valence electron arrangement.
  • Chemical compounds are named based upon the type of bonds formed by their constituent atoms/ ions.
  • Different patterns may be observed at the atomic/ molecular level and the macroscopic level.

Vocabulary

  • Protons
  • Neutrons
  • Nucleus
  • Electrons
  • Valence
  • Main group elements
  • Properties
  • Atoms
  • Elements
  • Periods/ Rows
  • Groups/ Families/ Columns
  • Atomic/ molecular level
  • Macroscopic level
  • Periodic trends
  • metal/ nonmetal/ metalloid behavior
  • electrical/ heat conductivity
  • electronegativity
  • electron affinity
  • ionization energy
  • atomic-covalent/ ionic radii
  • Molecular modeling
  • Lewis dot
  • 3-D ball-and-stick
  • space-filling
  • VSEPR
  • Types of bonds
  • ionic bonds
  • covalent/ molecular bonds
  • metallic bonds
  • Molecular shapes
  • Ions
  • Ionic compounds
  • Covalent/ molecular compounds

SC15.CHM.3a

Analyze data such as physical properties to explain periodic trends of the elements, including metal/nonmetal/metalloid behavior, electrical/heat conductivity, electronegativity and electron affinity, ionization energy, and atomic-covalent/ionic radii, and how they relate to position in the periodic table.

SC15.CHM.3b

Develop and use models (e.g., Lewis dot, 3-D ball-and-stick, space-filling, valence-shell electron-pair repulsion [VSEPR]) to predict the type of bonding and shape of simple compounds.

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