Gizmos for Florida - Science: Grades 9-12 (Next Generation Sunshine State Standards adopted 2008)

This correlation lists the recommended Gizmos for this state's curriculum standards. Click any Gizmo title below for more information.

SC.912.CS-CC: : Computer Science - Communication and Collaboration

SC.912.CS-CC.1: : Communication and collaboration

SC.912.CS-CC.1.1: : Evaluate modes of communication and collaboration.

SC.912.CS-CC.1.5: : Communicate and publish key ideas and details to a variety of audiences using digital tools and media-rich resources.

SC.912.CS-CS: : Computer Science - Communication Systems and Computing

SC.912.CS-CS.1: : Modeling and simulations

SC.912.CS-CS.1.1: : Analyze data and identify real-world patterns through modeling and simulation.

SC.912.CS-CS.1.2: : Formulate, refine, and test scientific hypotheses using models and simulations.

SC.912.CS-CS.1.3: : Explain how data analysis is used to enhance the understanding of complex natural and human systems.

SC.912.CS-CS.1.5: : Represent and understand natural phenomena using modeling and simulation.

SC.912.CS-CS.2: : Problem solving and Algorithms

SC.912.CS-CS.2.1: : Explain intractable problems and understand that problems exists that are computationally unsolvable (e.g., classic intractable problems include the Towers of Hanoi and the Traveling Salesman Problem -TSP).

SC.912.CS-CS.6: : Human – Computer interactions and Artificial Intelligence

SC.912.CS-CS.6.4: : Explain the notion of intelligent behavior through computer modeling and robotics.

SC.912.CS-CS.6.7: : Describe major applications of artificial intelligence and robotics, including, but not limited to, the medical, space, and automotive fields.

SC.912.CS-CP: : Computer Science - Computer Practices and Programming

SC.912.CS-CP.1: : Data analysis

SC.912.CS-CP.1.2: : Perform advanced searches to locate information and/or design a data-collection approach to gather original data (e.g., qualitative interviews, surveys, prototypes, and simulations).

SC.912.CS-CP.1.3: : Analyze and manipulate data collected by a variety of data collection techniques to support a hypothesis.

SC.912.CS-CP.1.4: : Collect real-time data from sources such as simulations, scientific and robotic sensors, and device emulators, using this data to formulate strategies or algorithms to solve advanced problems.

SC.912.CS-PC: : Computer Science - Personal, Community, Global, and Ethical Impact

SC.912.CS-PC.2: : The impact of computing resources on local and global society

SC.912.CS-PC.2.11: : Construct writings and/or communications using developmentally appropriate terminology.

SC.912.E: : Earth and Space

SC.912.E.5: : Earth in Space and Time

SC.912.E.5.1: : Cite evidence used to develop and verify the scientific theory of the Big Bang (also known as the Big Bang Theory) of the origin of the universe.

SC.912.E.5.3: : Describe and predict how the initial mass of a star determines its evolution.

SC.912.E.5.6: : Develop logical connections through physical principles, including Kepler's and Newton's Laws about the relationships and the effects of Earth, Moon, and Sun on each other.

SC.912.E.5.8: : Connect the concepts of radiation and the electromagnetic spectrum to the use of historical and newly-developed observational tools.

SC.912.E.6: : Earth Structures

SC.912.E.6.1: : Describe and differentiate the layers of Earth and the interactions among them.

SC.912.E.6.2: : Connect surface features to surface processes that are responsible for their formation.

SC.912.E.6.3: : Analyze the scientific theory of plate tectonics and identify related major processes and features as a result of moving plates.

SC.912.E.7: : Earth Systems and Patterns

SC.912.E.7.1: : Analyze the movement of matter and energy through the different biogeochemical cycles, including water and carbon.

SC.912.E.7.2: : Analyze the causes of the various kinds of surface and deep water motion within the oceans and their impacts on the transfer of energy between the poles and the equator.

SC.912.E.7.3: : Differentiate and describe the various interactions among Earth systems, including: atmosphere, hydrosphere, cryosphere, geosphere, and biosphere.

SC.912.E.7.4: : Summarize the conditions that contribute to the climate of a geographic area, including the relationships to lakes and oceans.

SC.912.E.7.6: : Relate the formation of severe weather to the various physical factors.

SC.912.E.7.7: : Identify, analyze, and relate the internal (Earth system) and external (astronomical) conditions that contribute to global climate change.

SC.912.L: : Life Science

SC.912.L.14: : Organization and Development of Living Organisms

SC.912.L.14.2: : Relate structure to function for the components of plant and animal cells. Explain the role of cell membranes as a highly selective barrier (passive and active transport).

SC.912.L.14.3: : Compare and contrast the general structures of plant and animal cells. Compare and contrast the general structures of prokaryotic and eukaryotic cells.

SC.912.L.14.34: : Describe the composition and physiology of blood, including that of the plasma and the formed elements.

SC.912.L.14.36: : Describe the factors affecting blood flow through the cardiovascular system.

SC.912.L.14.38: : Describe normal heart sounds and what they mean.

SC.912.L.14.46: : Describe the physiology of the digestive system, including mechanical digestion, chemical digestion, absorption and the neural and hormonal mechanisms of control.

SC.912.L.14.50: : Describe the structure of vertebrate sensory organs. Relate structure to function in vertebrate sensory systems.

SC.912.L.14.53: : Discuss basic classification and characteristics of plants. Identify bryophytes, pteridophytes, gymnosperms, and angiosperms.

SC.912.L.15: : Diversity and Evolution of Living Organisms

SC.912.L.15.1: : Explain how the scientific theory of evolution is supported by the fossil record, comparative anatomy, comparative embryology, biogeography, molecular biology, and observed evolutionary change.

SC.912.L.15.4: : Describe how and why organisms are hierarchically classified and based on evolutionary relationships.

SC.912.L.15.5: : Explain the reasons for changes in how organisms are classified.

SC.912.L.15.6: : Discuss distinguishing characteristics of the domains and kingdoms of living organisms.

SC.912.L.15.10: : Identify basic trends in hominid evolution from early ancestors six million years ago to modern humans, including brain size, jaw size, language, and manufacture of tools.

SC.912.L.15.11: : Discuss specific fossil hominids and what they show about human evolution.

SC.912.L.15.12: : List the conditions for Hardy-Weinberg equilibrium in a population and why these conditions are not likely to appear in nature. Use the Hardy-Weinberg equation to predict genotypes in a population from observed phenotypes.

SC.912.L.15.13: : Describe the conditions required for natural selection, including: overproduction of offspring, inherited variation, and the struggle to survive, which result in differential reproductive success.

SC.912.L.15.14: : Discuss mechanisms of evolutionary change other than natural selection such as genetic drift and gene flow.

SC.912.L.15.15: : Describe how mutation and genetic recombination increase genetic variation.

SC.912.L.16: : Heredity and Reproduction

SC.912.L.16.1: : Use Mendel's laws of segregation and independent assortment to analyze patterns of inheritance.

SC.912.L.16.2: : Discuss observed inheritance patterns caused by various modes of inheritance, including dominant, recessive, codominant, sex-linked, polygenic, and multiple alleles.

SC.912.L.16.4: : Explain how mutations in the DNA sequence may or may not result in phenotypic change. Explain how mutations in gametes may result in phenotypic changes in offspring.

SC.912.L.16.5: : Explain the basic processes of transcription and translation, and how they result in the expression of genes.

SC.912.L.16.6: : Discuss the mechanisms for regulation of gene expression in prokaryotes and eukaryotes at transcription and translation level.

SC.912.L.16.7: : Describe how viruses and bacteria transfer genetic material between cells and the role of this process in biotechnology.

SC.912.L.16.10: : Evaluate the impact of biotechnology on the individual, society and the environment, including medical and ethical issues.

SC.912.L.16.11: : Discuss the technologies associated with forensic medicine and DNA identification, including restriction fragment length polymorphism (RFLP) analysis.

SC.912.L.16.14: : Describe the cell cycle, including the process of mitosis. Explain the role of mitosis in the formation of new cells and its importance in maintaining chromosome number during asexual reproduction.

SC.912.L.16.16: : Describe the process of meiosis, including independent assortment and crossing over. Explain how reduction division results in the formation of haploid gametes or spores.

SC.912.L.16.17: : Compare and contrast mitosis and meiosis and relate to the processes of sexual and asexual reproduction and their consequences for genetic variation.

SC.912.L.17: : Interdependence

SC.912.L.17.3: : Discuss how various oceanic and freshwater processes, such as currents, tides, and waves, affect the abundance of aquatic organisms.

SC.912.L.17.4: : Describe changes in ecosystems resulting from seasonal variations, climate change and succession.

SC.912.L.17.5: : Analyze how population size is determined by births, deaths, immigration, emigration, and limiting factors (biotic and abiotic) that determine carrying capacity.

SC.912.L.17.7: : Characterize the biotic and abiotic components that define freshwater systems, marine systems and terrestrial systems.

SC.912.L.17.8: : Recognize the consequences of the losses of biodiversity due to catastrophic events, climate changes, human activity, and the introduction of invasive, non-native species.

SC.912.L.17.9: : Use a food web to identify and distinguish producers, consumers, and decomposers. Explain the pathway of energy transfer through trophic levels and the reduction of available energy at successive trophic levels.

SC.912.L.17.10: : Diagram and explain the biogeochemical cycles of an ecosystem, including water, carbon, and nitrogen cycle.

SC.912.L.17.12: : Discuss the political, social, and environmental consequences of sustainable use of land.

SC.912.L.17.13: : Discuss the need for adequate monitoring of environmental parameters when making policy decisions.

SC.912.L.17.14: : Assess the need for adequate waste management strategies.

SC.912.L.17.16: : Discuss the large-scale environmental impacts resulting from human activity, including waste spills, oil spills, runoff, greenhouse gases, ozone depletion, and surface and groundwater pollution.

SC.912.L.17.20: : Predict the impact of individuals on environmental systems and examine how human lifestyles affect sustainability.

SC.912.L.18: : Matter and Energy Transformations

SC.912.L.18.1: : Describe the basic molecular structures and primary functions of the four major categories of biological macromolecules.

SC.912.L.18.2: : Describe the important structural characteristics of monosaccharides, disaccharides, and polysaccharides and explain the functions of carbohydrates in living things.

SC.912.L.18.3: : Describe the structures of fatty acids, triglycerides, phospholipids, and steroids. Explain the functions of lipids in living organisms. Identify some reactions that fatty acids undergo. Relate the structure and function of cell membranes.

SC.912.L.18.4: : Describe the structures of proteins and amino acids. Explain the functions of proteins in living organisms. Identify some reactions that amino acids undergo. Relate the structure and function of enzymes.

SC.912.L.18.7: : Identify the reactants, products, and basic functions of photosynthesis.

SC.912.L.18.8: : Identify the reactants, products, and basic functions of aerobic and anaerobic cellular respiration.

SC.912.L.18.9: : Explain the interrelated nature of photosynthesis and cellular respiration.

SC.912.L.18.10: : Connect the role of adenosine triphosphate (ATP) to energy transfers within a cell.

SC.912.L.18.11: : Explain the role of enzymes as catalysts that lower the activation energy of biochemical reactions. Identify factors, such as pH and temperature, and their effect on enzyme activity.

SC.912.N: : Nature of Science

SC.912.N.1: : The Practice of Science

SC.912.N.1.1: : Define a problem based on a specific body of knowledge, for example: biology, chemistry, physics, and earth/space science, and do the following:

SC.912.N.1.1.1: : Pose questions about the natural world,

SC.912.N.1.1.2: : Conduct systematic observations,

SC.912.N.1.1.5: : Plan investigations,

SC.912.N.1.1.6: : Use tools to gather, analyze, and interpret data (this includes the use of measurement in metric and other systems, and also the generation and interpretation of graphical representations of data, including data tables and graphs),

SC.912.N.1.1.7: : Pose answers, explanations, or descriptions of events,

SC.912.N.1.1.8: : Generate explanations that explicate or describe natural phenomena (inferences),

SC.912.N.1.1.9: : Use appropriate evidence and reasoning to justify these explanations to others,

SC.912.N.1.1.10: : Communicate results of scientific investigations, and

SC.912.N.1.2: : Describe and explain what characterizes science and its methods.

SC.912.N.1.3: : Recognize that the strength or usefulness of a scientific claim is evaluated through scientific argumentation, which depends on critical and logical thinking, and the active consideration of alternative scientific explanations to explain the data presented.

SC.912.N.1.6: : Describe how scientific inferences are drawn from scientific observations and provide examples from the content being studied.

SC.912.N.1.7: : Recognize the role of creativity in constructing scientific questions, methods and explanations.

SC.912.N.2: : The Characteristics of Scientific Knowledge

SC.912.N.2.2: : Identify which questions can be answered through science and which questions are outside the boundaries of scientific investigation, such as questions addressed by other ways of knowing, such as art, philosophy, and religion.

SC.912.N.2.4: : Explain that scientific knowledge is both durable and robust and open to change. Scientific knowledge can change because it is often examined and re-examined by new investigations and scientific argumentation. Because of these frequent examinations, scientific knowledge becomes stronger, leading to its durability.

SC.912.N.3: : The Role of Theories, Laws, Hypotheses, and Models

SC.912.N.3.1: : Explain that a scientific theory is the culmination of many scientific investigations drawing together all the current evidence concerning a substantial range of phenomena; thus, a scientific theory represents the most powerful explanation scientists have to offer.

SC.912.N.3.5: : Describe the function of models in science, and identify the wide range of models used in science.

SC.912.P: : Physical Science

SC.912.P.8: : Matter

SC.912.P.8.1: : Differentiate among the four states of matter.

SC.912.P.8.2: : Differentiate between physical and chemical properties and physical and chemical changes of matter.

SC.912.P.8.3: : Explore the scientific theory of atoms (also known as atomic theory) by describing changes in the atomic model over time and why those changes were necessitated by experimental evidence.

SC.912.P.8.4: : Explore the scientific theory of atoms (also known as atomic theory) by describing the structure of atoms in terms of protons, neutrons and electrons, and differentiate among these particles in terms of their mass, electrical charges and locations within the atom.

SC.912.P.8.5: : Relate properties of atoms and their position in the periodic table to the arrangement of their electrons.

SC.912.P.8.6: : Distinguish between bonding forces holding compounds together and other attractive forces, including hydrogen bonding and van der Waals forces.

SC.912.P.8.7: : Interpret formula representations of molecules and compounds in terms of composition and structure.

SC.912.P.8.8: : Characterize types of chemical reactions, for example: redox, acid-base, synthesis, and single and double replacement reactions.

SC.912.P.8.9: : Apply the mole concept and the law of conservation of mass to calculate quantities of chemicals participating in reactions.

SC.912.P.8.11: : Relate acidity and basicity to hydronium and hydroxyl ion concentration and pH.

SC.912.P.8.12: : Describe the properties of the carbon atom that make the diversity of carbon compounds possible.

SC.912.P.10: : Energy

SC.912.P.10.1: : Differentiate among the various forms of energy and recognize that they can be transformed from one form to others.

SC.912.P.10.2: : Explore the Law of Conservation of Energy by differentiating among open, closed, and isolated systems and explain that the total energy in an isolated system is a conserved quantity.

SC.912.P.10.3: : Compare and contrast work and power qualitatively and quantitatively.

SC.912.P.10.4: : Describe heat as the energy transferred by convection, conduction, and radiation, and explain the connection of heat to change in temperature or states of matter.

SC.912.P.10.5: : Relate temperature to the average molecular kinetic energy.

SC.912.P.10.6: : Create and interpret potential energy diagrams, for example: chemical reactions, orbits around a central body, motion of a pendulum.

SC.912.P.10.7: : Distinguish between endothermic and exothermic chemical processes.

SC.912.P.10.9: : Describe the quantization of energy at the atomic level.

SC.912.P.10.10: : Compare the magnitude and range of the four fundamental forces (gravitational, electromagnetic, weak nuclear, strong nuclear).

SC.912.P.10.11: : Explain and compare nuclear reactions (radioactive decay, fission and fusion), the energy changes associated with them and their associated safety issues.

SC.912.P.10.12: : Differentiate between chemical and nuclear reactions.

SC.912.P.10.13: : Relate the configuration of static charges to the electric field, electric force, electric potential, and electric potential energy.

SC.912.P.10.14: : Differentiate among conductors, semiconductors, and insulators.

SC.912.P.10.15: : Investigate and explain the relationships among current, voltage, resistance, and power.

SC.912.P.10.16: : Explain the relationship between moving charges and magnetic fields, as well as changing magnetic fields and electric fields, and their application to modern technologies.

SC.912.P.10.18: : Explore the theory of electromagnetism by comparing and contrasting the different parts of the electromagnetic spectrum in terms of wavelength, frequency, and energy, and relate them to phenomena and applications.

SC.912.P.10.19: : Explain that all objects emit and absorb electromagnetic radiation and distinguish between objects that are blackbody radiators and those that are not.

SC.912.P.10.20: : Describe the measurable properties of waves and explain the relationships among them and how these properties change when the wave moves from one medium to another.

SC.912.P.10.21: : Qualitatively describe the shift in frequency in sound or electromagnetic waves due to the relative motion of a source or a receiver.

SC.912.P.10.22: : Construct ray diagrams and use thin lens and mirror equations to locate the images formed by lenses and mirrors.

SC.912.P.12: : Motion

SC.912.P.12.1: : Distinguish between scalar and vector quantities and assess which should be used to describe an event.

SC.912.P.12.2: : Analyze the motion of an object in terms of its position, velocity, and acceleration (with respect to a frame of reference) as functions of time.

SC.912.P.12.3: : Interpret and apply Newton's three laws of motion.

SC.912.P.12.4: : Describe how the gravitational force between two objects depends on their masses and the distance between them.

SC.912.P.12.5: : Apply the law of conservation of linear momentum to interactions, such as collisions between objects.

SC.912.P.12.10: : Interpret the behavior of ideal gases in terms of kinetic molecular theory.

SC.912.P.12.11: : Describe phase transitions in terms of kinetic molecular theory.

SC.912.P.12.12: : Explain how various factors, such as concentration, temperature, and presence of a catalyst affect the rate of a chemical reaction.

Correlation last revised: 2/22/2023

Florida - Science: Grades 9-12

Next Generation Sunshine State Standards | Adopted: 2008