23 results found for 'Waves'. Prev | View 100 per page Strip plurals: waves to wav Waves to Waves
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Energy Transfer - Energy transfer through different mediums can be explained using wave and particle models ACSPH060 Year 11 Linear Motion and Waves
Linear motion and force - Uniformly accelerated motion is described in terms of relationships between measurable scalar and vector quantities, including displacement, speed, velocity and acceleration ACSPH061 Year 11 Linear Motion and Waves
Linear motion and force - Representations, including graphs and vectors, and/or equations of motion, can be used qualitatively and quantitatively to describe and predict linear motion ACSPH062 Year 11 Linear Motion and Waves
Linear motion and force - Vertical motion is analysed by assuming the acceleration due to gravity is constant near Earth’s surface ACSPH063 Year 11 Linear Motion and Waves
Linear motion and force - Newton’s Three Laws of Motion describe the relationship between the force or forces acting on an object, modelled as a point mass, and the motion of the object due to the application of the force or forces ACSPH064 Year 11 Linear Motion and Waves
Linear motion and force - Momentum is a property of moving objects; it is conserved in a closed system and may be transferred from one object to another when a force acts over a time interval ACSPH065 Year 11 Linear Motion and Waves
Linear motion and force - Energy is conserved in isolated systems and is transferred from one object to another when a force is applied over a distance; this causes work to be done and changes to kinetic and/or potential energy of objects ACSPH066 Year 11 Linear Motion and Waves
Linear motion and force - Collisions may be elastic and inelastic; kinetic energy is conserved in elastic collisions ACSPH069 Year 11 Linear Motion and Waves
Waves - Waves may be represented by time and displacement wave diagrams and described in terms of relationships between measurable quantities, including period, amplitude, wavelength, frequency and velocity ACSPH072 Year 11 Linear Motion and Waves
Waves - The superposition of waves in a medium may lead to the formation of standing waves and interference phenomena, including standing waves in pipes and on stretched strings ACSPH073 Year 11 Linear Motion and Waves
Waves - A mechanical system resonates when it is driven at one of its natural frequencies of oscillation; energy is transferred efficiently into systems under these conditions ACSPH076 Year 11 Linear Motion and Waves
Waves - A wave model explains a wide range of lightrelated phenomena including reflection, refraction, total internal reflection, dispersion, diffraction and interference; a transverse wave model is required to explain polarisation ACSPH067 Year 11 Linear Motion and Waves
Waves - Waves are periodic oscillations that transfer energy from one point to another ACSPH068 Year 11 Linear Motion and Waves
Waves - Longitudinal and transverse waves are distinguished by the relationship between the direction of oscillation relative to the direction of the wave velocity ACSPH070 Year 11 Linear Motion and Waves
Waves - Mechanical waves transfer energy through a medium; mechanical waves may oscillate the medium or oscillate the pressure within the medium ACSPH071 Year 11 Linear Motion and Waves
Waves - The mechanical wave model can be used to explain phenomena related to reflection and refraction ACSPH074 Year 11 Linear Motion and Waves
Waves - Light exhibits many wave properties; however, it cannot be modelled as a mechanical wave because it can travel through a vacuum ACSPH075 Year 11 Linear Motion and Waves
Waves - A ray model of light may be used to describe reflection, refraction and image formation from lenses and mirrors ACSPH077 Year 11 Linear Motion and Waves
Waves - The speed of light is finite and many orders of magnitude greater than the speed of mechanical waves (for example, sound and water waves); its intensity decreases in an inverse square relationship with distance from a point source ACSPH140 Year 12 Revolutions in modern physics
Quantum theory - On the atomic level, energy and matter exhibit the characteristics of both waves and particles
23 results found for 'Waves'. Prev | View 100 per page
Low relevance matches: 5 other results may be of interest to you. Show low relevance matches
Curriculum resources related to 'Waves'
ACSSU182 Year 9 Physical SciencesEnergy Transfer - Energy transfer through different mediums can be explained using wave and particle models ACSPH060 Year 11 Linear Motion and Waves
Linear motion and force - Uniformly accelerated motion is described in terms of relationships between measurable scalar and vector quantities, including displacement, speed, velocity and acceleration ACSPH061 Year 11 Linear Motion and Waves
Linear motion and force - Representations, including graphs and vectors, and/or equations of motion, can be used qualitatively and quantitatively to describe and predict linear motion ACSPH062 Year 11 Linear Motion and Waves
Linear motion and force - Vertical motion is analysed by assuming the acceleration due to gravity is constant near Earth’s surface ACSPH063 Year 11 Linear Motion and Waves
Linear motion and force - Newton’s Three Laws of Motion describe the relationship between the force or forces acting on an object, modelled as a point mass, and the motion of the object due to the application of the force or forces ACSPH064 Year 11 Linear Motion and Waves
Linear motion and force - Momentum is a property of moving objects; it is conserved in a closed system and may be transferred from one object to another when a force acts over a time interval ACSPH065 Year 11 Linear Motion and Waves
Linear motion and force - Energy is conserved in isolated systems and is transferred from one object to another when a force is applied over a distance; this causes work to be done and changes to kinetic and/or potential energy of objects ACSPH066 Year 11 Linear Motion and Waves
Linear motion and force - Collisions may be elastic and inelastic; kinetic energy is conserved in elastic collisions ACSPH069 Year 11 Linear Motion and Waves
Waves - Waves may be represented by time and displacement wave diagrams and described in terms of relationships between measurable quantities, including period, amplitude, wavelength, frequency and velocity ACSPH072 Year 11 Linear Motion and Waves
Waves - The superposition of waves in a medium may lead to the formation of standing waves and interference phenomena, including standing waves in pipes and on stretched strings ACSPH073 Year 11 Linear Motion and Waves
Waves - A mechanical system resonates when it is driven at one of its natural frequencies of oscillation; energy is transferred efficiently into systems under these conditions ACSPH076 Year 11 Linear Motion and Waves
Waves - A wave model explains a wide range of lightrelated phenomena including reflection, refraction, total internal reflection, dispersion, diffraction and interference; a transverse wave model is required to explain polarisation ACSPH067 Year 11 Linear Motion and Waves
Waves - Waves are periodic oscillations that transfer energy from one point to another ACSPH068 Year 11 Linear Motion and Waves
Waves - Longitudinal and transverse waves are distinguished by the relationship between the direction of oscillation relative to the direction of the wave velocity ACSPH070 Year 11 Linear Motion and Waves
Waves - Mechanical waves transfer energy through a medium; mechanical waves may oscillate the medium or oscillate the pressure within the medium ACSPH071 Year 11 Linear Motion and Waves
Waves - The mechanical wave model can be used to explain phenomena related to reflection and refraction ACSPH074 Year 11 Linear Motion and Waves
Waves - Light exhibits many wave properties; however, it cannot be modelled as a mechanical wave because it can travel through a vacuum ACSPH075 Year 11 Linear Motion and Waves
Waves - A ray model of light may be used to describe reflection, refraction and image formation from lenses and mirrors ACSPH077 Year 11 Linear Motion and Waves
Waves - The speed of light is finite and many orders of magnitude greater than the speed of mechanical waves (for example, sound and water waves); its intensity decreases in an inverse square relationship with distance from a point source ACSPH140 Year 12 Revolutions in modern physics
Quantum theory - On the atomic level, energy and matter exhibit the characteristics of both waves and particles
Products related to 'Waves'
23 results found for 'Waves'. Prev | View 100 per page
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