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Topic

Essential Idea

Understandings

Applications

Guidance

DB Reference

UNIT 1: Measurements & Uncertainties

1.1

Measurements in Physics

Since 1948, the Système International d’Unités (SI) has been used as the preferred language of science and technology across the globe and reflects current best measurement practice.

Fundamental SI Units

Scientific Notation & Metric Multipliers

Significant Figures

Orders of Magnitude

Estimation

1.2

Uncertainties & Errors

Scientists aim towards designing experiments that can give a “true value” from their measurements, but due to the limited precision in measuring devices, they often quote their results with some form of uncertainty.

Errors: Random & Systematic

Uncertainties: Absolute, Fractional & Percentage

Error Bars

Uncertainty of Gradient & Intercepts

1.3

Vectors & Scalars

Some quantities have direction and magnitude, others have magnitude only, and this understanding is the key to correct manipulation of quantities. This sub topic will have broad applications across multiple fields within physics and other sciences

Types of Quantities: Vector & Scalar

Combination and Resolution of Vectors

UNIT 2: Mechanics

2.1

Motion

Motion may be described and analyzed by the use of graphs and equations.

Distance & Displacement

Speed & Velocity

Acceleration

Graphs describing motion

Equations of motion for Uniform Acceleration

Projectile Motion

Fluid Resistance & Terminal Speed

2.2

Forces

Classical physics requires a force to change a state of motion, as suggested by Newton in his laws of motion.

Objects as Point Particles

Free-body Diagrams

Translational Equilibrium

Newton’s Laws of Motion

Solid Friction

2.3

Work Energy & Power

The fundamental concept of energy lays the basis upon which much of science is built.

Types of Energy: Kinetic, Gravitational potential & Elastic potential

Work Done as energy transfer

Power as Rate of energy transfer

Principle of Conservation of Energy

Efficiency

2.4

Momentum & Impulse

Conservation of momentum is an example of a law that is never violated.

Newton’s Second Law expressed in terms of rate of change of momentum

Graphs: Impulse—time & Force—time

Conservation of Linear Momentum

Collisions: Elastic, Inelastic & Explosions

UNIT 3: Thermal

3.1

Thermal Concepts

Thermal physics deftly demonstrates the links between the macroscopic measurements essential to many scientific models with the microscopic properties that underlie these models.

Molecular Theory of solids, liquids & gases

Temperature (including Absolute Temperature)

Internal Energy

Specific Heat Capacity

Phase Change

Specific Latent Heat

3.2

Modelling a Gas

The properties of ideal gases allow scientists to make predictions of the behavior of real gases.

Pressure

Equation of State for an idea gas

Kinetic Model of an ideal gas

Mole, Molar Mass & the Avogadro Constant

Differences between Real and Ideal Gases

UNIT 4: Waves

4.1

Oscillations

A study of oscillations underpins many areas of physics with simple harmonic motion (SHM), a fundamental oscillation that appears in various natural phenomena.

Simple Harmonic Oscillations

Time Period, Frequency, Amplitude, Displacement & Phase Difference

Conditions for SHM

4.2

Travelling Waves

There are many forms of waves available to be studied. A common characteristic of all travelling waves is that they carry energy, but generally the medium through which they travel will not be permanently disturbed.

Travelling Waves

Wavelength, Frequency, Period & Wave Speed

Transverse & Longitudinal waves

Nature of EM waves

Nature of Sound waves

4.3

Wave Characteristics

All waves can be described by the same sets of mathematical ideas. Detailed knowledge of one area leads to the possibility of prediction in another.

Wavefronts & Rays

Amplitude & Intensity

Superposition

Polarization

4.4

Wave Behavior

Waves interact with media and each other in a number of ways that can be unexpected and useful.

Reflection & Refraction

Snell’s Law, Critical Angle & Total Internal Reflection

Diffraction through a Single-slit and around objects

Interference Patterns

Double-slit interference

Path Difference

4.5

Standing Waves

When travelling waves meet they can superpose to form standing waves in which energy may not be transferred.

Nature of Standing Wave

Boundary Conditions

Nodes & Antinodes

UNIT 5: Electromagnetism

5.1

Electric Fields

When charges move an electric current is created.

Charge

Electric Field

Coulomb’s Law

Electric Current

Direct Current (DC)

Potential Difference

5.2

Heating Effect of Electric Currents

One of the earliest uses for electricity was to produce light and heat. This technology continues to have a major impact on the lives of people around the world.

Circuit Diagrams

Kirchoff’s Circuit Laws

Heating effect of current and its consequences

Resistance as

Ohm’s Law

Resistivity (of material)

Power Dissipation

5.3

Electric Cells

Electric cells allow us to store energy in a chemical form.

Cells

Internal Resistance

Secondary Cells

Terminal Potential Difference

Electromotive Force (EMF)

5.4

Magnetic Effects of Electric Currents

The effect scientists call magnetism arises when one charge moves in the vicinity of another moving charge.

Magnetic Fields

Magnetic Force

UNIT 6: Circular Motion & Gravitation

6.1

Circular Motion

A force applied perpendicular to its displacement can result in circular motion.

Period, Frequency, Angular Displacement & Angular Velocity

Centripetal Force

Centripetal Acceleration

6.2

Newton’s Law of Gravitation

The Newtonian idea of gravitational force acting between two spherical bodies and the laws of mechanics create a model that can be used to calculate the motion of planets.

Newton’s Law of Gravitation

Gravitational Field Strength

UNIT 7: Atomic Nuclear & Particle Physics

7.1

Discrete Energy & Radioactivity

In the microscopic world energy is discrete.

Discrete Energy & Discrete energy Levels

Transitions between energy levels

Radioactive Decay

Fundamental Forces (and their properties)

Alpha Particles, Beta Particles & Gamma Rays

Half-life

Absorption Characteristics of decay particles

Isotopes

Background Radiation

7.2

Nuclear Reactions

Energy can be released in nuclear decays and reactions as a result of the relationship between mass and energy.

Unified Atomic Mass Unit (u)

Mass Defect & Nuclear Binding Energy

Nuclear Fission & Fusion

7.3

Structure of Matter

It is believed that all the matter around us is made up of fundamental particles called quarks and leptons. It is known that matter has a hierarchical structure with quarks making up nucleons, nucleons making up nuclei, nuclei and electrons making up atoms and atoms making up molecules. In this hierarchical structure, the smallest scale is seen for quarks and leptons (10^–18 m).

Fermions: Quarks & Leptons & their Antiparticles

Hadrons: Baryons & Mesons

Conservation Laws: Charge, Baryon Number, Lepton Number & Strangeness

Nature and Range of: Strong, Weak & EM Forces

Exchange Particles: W, Z, gluons & photons

Feynman Diagrams

(Quark) Confinement

The Higgs Boson

UNIT 8: Energy production

8.1

Energy Sources

The constant need for new energy sources implies decisions that may have a serious effect on the environment. The finite quantity of fossil fuels and their implication in global warming has led to the development of alternative sources of energy. This continues to be an area of rapidly changing technological innovation.

Specific Energy & Energy Density of fuels

Sankey Diagrams

Primary energy sources

Electricity as a secondary and versatile form of energy

Renewable & Non-renewable sources

8.2

Thermal Energy Transfer

For simplified modelling purposes the Earth can be treated as a black-body radiator and the atmosphere treated as a grey-body.

Conduction, Convection & (thermal) Radiation

Black-body Radiation

Albedo & Emissivity

The Solar Constant

Greenhouse Effect

Energy balance in the Earth surface-atmosphere system

AHL 9: Wave Phenomena

9.1

Simple Harmonic Motion

The solution of the harmonic oscillator can be framed around the variation of kinetic and potential energy in the system.

The defining equation of SHM

Energy Changes

9.2

Single-slit Diffraction

Single-slit diffraction occurs when a wave is incident upon a slit of approximately the same size as the wavelength.

Nature of single-slit Diffraction

Describe effect of slit width on diffraction pattern

Determine position of first interference minimum

Describe qualitatively single-slit diffraction patterns produced from white light / range of monochromatic sources

Only rectangular slits need to be considered

Diffraction around an object does not need to be considered (it is in unit 4)

Be aware of approximate ratios of intensities of successive maxima

…

9.3

Interference

Interference patterns from multiple slits and thin films produce accurately repeatable patterns.

Young’s Double-slit Experiment

Modulation (enveloping) of two-slit interference pattern by one-slit diffraction effect

Multiple-slit / Diffraction Grating interference patterns

Thin Film Interference

Describe qualitatively two-slit interference patterns, including single-slit modulation

Sketch & interpret intensity graphs of two-slit interference patterns

Use the diffraction grating equation

Describe conditions necessary for constructive and destructive interference from thin films, including boundary phase change and effect of refraction

9.4

Resolution

Resolution places an absolute limit on the extent to which an optical or other system can separate images of objects.

Size of a Diffracting Aperture

Resolution of simple monochromatic Two-source Systems

Use the Rayleigh criterion for light emitted by two sources diffracted at a single slit

Resolvance of diffraction gratings

Proof of the diffraction grating resolvance equation is not required

9.5

Doppler Effect

The Doppler effect describes the phenomenon of wavelength/frequency shift when relative motion occurs.

Doppler Effect (for sound & light waves)

Sketch and interpret the Doppler effect for relative motion between source and observer

Describe situations were the Doppler effect can be utilized

Use frequency/velocity/wavelength change formulas

For EM wave, the approximate (non-relativistic) equation should be used for all calculations

…

AHL 10: Fields

10.1

Describing Fields

Electric charges and masses each influence the space around them and that influence can be represented through the concept of fields.

Fields: Gravitational & Electrostatic

Potentials: Gravitational & Electric

Field Lines

Equipotential Surfaces

10.2

Fields at Work

Similar approaches can be taken in analyzing electrical and gravitational potential problems.

(Field) Potential & Potential Energy

Potential Gradient (field strength)

Potential Difference

Escape Speed

Orbital Motion, Orbital Speed & Orbital (potential + kinetic) Energy

Forces and Inverse-square Law behavior

AHL 11: Induction

11.1

Electromagnetic Induction

The majority of electricity generated throughout the world is generated by machines that were designed to operate using the principles of electromagnetic induction.

Electromotive Force (EMF)

Magnetic Flux & Flux Linkage

Faraday’s Law of Induction

Lenz’s Law

11.2

Power Generation & Transmission

Generation and transmission of alternating current (ac) electricity has transformed the world.

Alternating Current (AC) Generators

Average Power & Root-mean-square (RMS) values of current & voltage

Transformers

Diode bridges (AC rectifiers)

Half-wave and Full-wave AC Rectification

11.3

Capacitance

Capacitors can be used to store electrical energy for later use.

Capacitance

Dielectric Materials

Capacitors in Series & Parallel

Resistor-capacity (RC) series Circuits

Time Constant (τ)

AHL 12: Quantum & Nuclear Physics

12.1

Interaction with Radiation

The microscopic quantum world offers a range of phenomena, the interpretation and explanation of which require new ideas and concepts not found in the classical world.

Photons

Photoelectric Effect

Matter Waves

Pair Production & Annihilation

Quantization of angular momentum in the Bohr model for hydrogen

The Wave Function

Uncertainty Principle for Energy-Time & Position-Momentum

Tunneling, Potential Barrier & Factors affecting tunnelling probability

Discuss the photoelectric effect experiment and explain which features of the experiment cannot be explained by the classical wave theory of light

Solve photoelectric problems both graphically and algebraically (formula)

Discuss experimental evidence for matter waves, including electron wave experiments

State order o magnitude estimates from the uncertainty principle

The order of magnitude estimates from the uncertainty principle may include estimates of the energy of the ground state of an atom, the impossibility of an electron existing within a nucleus, and the lifetime of an electron in a excited energy state

Tunnelling to be treated qualitatively using the idea of continuity of wave functions

energy of hydrogen atom electron shells

angular momentum of hydrogen atom electron

probability that an electron will be found within a volume

12.2

Nuclear Physics

The idea of discreteness that we met in the atomic world continues to exist in the nuclear world as well.

Rutherford Scattering and Nuclear Radius

Nuclear Energy Levels

The Neutrino

The Law of Radioactive Decay & Decay Constant

Describe a scattering experiment including location of minimum intensity for the diffracted particles based on their de Broglie wavelength

Explain deviations from Rutherford scattering in high energy experiments

Option B: Engineering

B.1

Rigid Bodies & Rotational Dynamics

The basic laws of mechanics have an extension when equivalent principles are applied to rotation. Actual objects have dimensions and they require the expansion of the point particle model to consider the possibility of different points on an object having different states of motion and/or different velocities.

Torque

Momentum of Inertia

Rotational & Translational Equilibrium

Angular Acceleration

Equations of rotational motion for uniform angular acceleration

Newton’s second law applied to angular motion

Conservation of Angular Momentum

B.2

Thermodynamics

The first law of thermodynamics relates the change in internal energy of a system to the energy transferred and the work done. The entropy of the universe tends to a maximum.

First Law of Thermodynamics

Second Law of Thermodynamics

Entropy

Cyclic Processes & pV Diagrams

Isovolumetric, Isobaric, Isothermal & Adiabatic Processes

Carnot Cycle

Thermal Efficiency

B.3

(HL)

Fluids & Fluid Dynamics

Fluids cannot be modelled as point particles. Their distinguishable response to compression from solids creates a set of characteristics that require an in depth study.

Density & Pressure

Buoyancy & Archimedes’ Principle

Pascal’s Principle

Hydrostatic Equilibrium

The Idea Fluid

Streamlines

The Continuity Equation

Bernoulli Effect & Equation

Stoke’s Law & Viscosity

Laminar & Turbulent Flow & Reynold’s Number

B.4

(HL)

Forced Vibrations & Resonance

In the real world, damping occurs in oscillators and has implications that need to be considered

Natural Frequency of vibration

Q Factor & Dampening

Periodic Stimulus & Driving Frequency

Resonance