Wave-particle duality

Wave-particle duality is a fundamental concept in quantum mechanics that describes the dual nature of particles, which can exhibit both wave-like and particle-like behaviour.

  • Wave-particle duality refers to the phenomenon where entities like light can exhibit characteristics of both waves and particles.
    •  Electromagnetic radiation, including light, is often described using wave properties. However, when it interacts with matter, it behaves like particles.
    •  A photon is a quantum of electromagnetic radiation and represents the smallest discrete amount of light energy.
    • When a photon is absorbed by matter, the energy becomes localized at specific points. This phenomenon is termed ‘wave function collapse.’ It describes the transition of a quantum system from a superposition of states to a definite state upon measurement.
    • Wave-particle duality is a fundamental aspect of quantum mechanics and applies to all particles, not just light. Particles like electrons also exhibit wave-like and particle-like behaviour.
  • The double-slit experiment is an experiment in quantum physics that demonstrates the wave-like behaviour of particles, including photons and electrons, and is a key illustration of wave-particle duality.

Concepts used to describe light as waves and particles can be paired to illustrate the wave-particle character of light

Wave concept
Particle concept
Explanation
FrequencyEnergyFrequency is related to the energy of a photon. Higher frequency light corresponds to higher energy photons. This is described by Planck's equation E = hf, where E is energy, h is Planck's constant, and f is frequency.
WavelengthMomentumThe wavelength of a wave is inversely proportional to its momentum. This is described by the de Broglie wavelength formula λ = h/p, where λ is wavelength, h is Planck's constant, and p is momentum.
Wave speedMomentumThe speed of a wave is related to its momentum through its frequency and wavelength. For light, the speed of propagation (c, the speed of light) is equal to its frequency times wavelength (c = λf), which is also related to its momentum as described above.
AmplitudeIntensityThe amplitude of a wave determines its intensity, which is related to the brightness or energy density of light. Higher amplitude corresponds to higher intensity.
PeriodLifetimeThe period of a wave is the time it takes for one complete cycle. In the context of light particles (photons), their "lifetime" refers to the duration of their existence before they are absorbed or undergo a different process.
PhaseQuantum statePhase refers to the position of a point in a wave cycle, and it can be related to the quantum state of a particle. In quantum mechanics, a particle's state is described by a complex-valued wavefunction, and the phase of this wavefunction is significant in determining probabilities and interference patterns.

These pairings are all based on the wave-particle duality of matter, which states that all objects have both wave-like and particle-like properties.

The specific pairings in the table can be derived from the following equations:

  • E = hf (Planck’s equation describes the relationship between the energy of a photon and its frequency.)
  • p = h/λ (de Broglie wavelength equation describes the relationship between the momentum of a particle and its wavelength.)
  • p = mv (momentum equation describes the relationship between the momentum of a particle and its mass and velocity.)
  • I = 1/2 cε_0 E^2 (intensity equation describes the relationship between the intensity of an electromagnetic wave and its electric field.)

where:

  • E is energy
  • f is frequency
  • p is momentum
  • m is mass
  • v is velocity
  • λ is wavelength
  • I is intensity
  • c is the speed of light
  • ε_0 is the permittivity of free space. The permittivity of free space, also known as the electric constant, is a fundamental constant of nature. It is a measure of how easily an electric field can penetrate a vacuum.

The equation E = hf tells us that the energy of a particle is proportional to its frequency. This means that the higher the frequency of a particle, the more energy it has. This is why high-frequency radiation, such as gamma rays and X-rays, is so dangerous.

The equation p = h/λ tells us that the momentum of a particle is inversely proportional to its wavelength. This means that the shorter the wavelength of a particle, the more momentum it has. This is why high-energy particles, such as protons and electrons, can be used to accelerate other particles to high speeds.

Wavefront

Electromagnetic waves that are parallel, share a common starting point, have the same frequency and phase, and move through the same medium, form an advancing wavefront at right angles to their direction of travel.

  • A wavefront is a conceptual tool used in the study of waves, including electromagnetic waves like light. It refers to the locus of all points that are in phase with each other along the wave at a given instant. In other words, it represents the leading edge of a wave as it propagates through a medium.
    • Sources that emit light in all directions, known as point sources, generate spherical wavefronts.
    • Lasers, which produce a narrow beam of parallel rays, create waves with flat wavefronts.
    • An electromagnetic wave with a flat wavefront is known as a plane wave.
  • In addition to plane waves and spherical waves, there are also cylindrical waves which are produced when a point source is extended along a straight line.
  • The shape of the wavefront can be influenced by interaction with different mediums or obstacles, such as when:
    • Refraction causes the path of light to bend as it crosses the boundary between two transparent media.
    • Dispersion causes light to separate into its constituent wavelengths, each of which bends to a different degree as it crosses the boundary between two transparent media.
    • Diffraction causes light to bend around the edges of obstacles into regions that would otherwise be in shadow.
  • The concept of wavefronts applies not only to light but also to other types of waves such as sound waves or water waves.
More about wavefronts
  • Wavefronts are typically used to describe the behaviour of waves in classical physics, where waves exhibit properties such as interference, diffraction, and refraction.
  • While wavefronts are often associated with the behaviour of light, which can exhibit both wave-like and particle-like properties, they are a description of the wave nature of light rather than individual photons.
  • At the quantum level, the behaviour of individual photons is described differently, often using concepts such as wave functions in quantum mechanics.

Wavelength

Wavelength is the distance from any point on a wave to the corresponding point on the next wave. This measurement is taken along the middle line of the wave.

  • While wavelength can be measured from any point on a wave, it is often simplest to measure from the peak of one wave to the peak of the next, or from the bottom of one trough to the bottom of the next, ensuring the measurement covers a whole wave cycle.
  • The wavelength of an electromagnetic wave is usually given in metres.
  • The wavelength of visible light is typically measured in nanometres, with 1,000,000,000 nanometres making up a metre.
  • Each type of electromagnetic radiation – such as radio waves, visible light, and gamma waves – corresponds to a specific range of wavelengths on the electromagnetic spectrum.
  • As energy increases, frequency also increases and the wavelength decreases. Therefore, shorter wavelengths correspond to higher energy levels, and longer wavelengths correspond to lower energy levels.
Wavelength & the Visible Spectrum
  • The visible part of the electromagnetic spectrum consists of a range of wavelengths that correspond with all the different colours we see in the world.
  • The visible spectrum, which spans wavelengths from approximately 400 to 700 nanometres, is commonly described in terms of bands of colour—red, orange, yellow, green, blue, indigo, and violet.
  • However, these divisions are somewhat arbitrary since the spectrum is continuous, and the exact wavelength boundaries between colours is subjective.
  • Humans don’t see the wavelengths of visible light directly but do see the specific colour associated with each wavelength and the colour produced when different wavelengths mix.
  • Within this visible spectrum, each colour corresponds to a single wavelength of light.
  • The concept of colour is a perceptual property, not a property of light itself.
  • It’s how our brain interprets the wavelengths of light that reach our eyes. The perceived colour (hue) of a light stimulus is dependent on its wavelength.
  • A colour produced by a single wavelength is known as a pure spectral colour.
Wavelength & Colour
  • A light that we perceive as white is a combination of many different wavelengths of light across the visible spectrum. When these wavelengths containing red, green, and blue mix and reflect off a neutral-coloured surface, they appear white to our eyes.
  • Light sources in nature rarely emit a single wavelength. They typically emit a mixture of many wavelengths that combine to create the colour we perceive upon reflection. The wider the range of wavelengths present in the light source, the less saturated (more diluted) the reflected colour will appear. In other words, light with a mix of many wavelengths tends to appear lighter or closer to white.
  • Wavelengths of visible light are typically measured in nanometers (nm). While the human eye cannot distinguish every single possible wavelength within the visible spectrum (between 400 nm and 700 nm), it can differentiate a vast range of colours within that spectrum.

Weak Nuclear force

The weak nuclear force is one of the four fundamental forces in nature, alongside the electromagnetic force, the strong nuclear force, and gravity. The weak nuclear force played a key role in the creation of elements like hydrogen, helium, and lithium in the early universe. Today, it plays a critical role in the nuclear fusion reactions that power the Sun and other stars.

  • The weak nuclear force is responsible for the decay of radioactive isotopes, as well as for other nuclear reactions such as beta decay and neutrino interactions.
  • When unstable radioactive isotopes decay, they emit radiation and transform into more stable elements.
  • In beta decay, a neutron in the nucleus of an atom decays into a proton, an electron, and an antineutrino. Neutrino interactions occur in nuclear reactors.
  • Neutrinos are very light particles that rarely interact with matter, but they can interact with the nuclei of atoms through the weak nuclear force.
  • The weak nuclear force is unique compared to other fundamental forces. It’s considered weak because its strength is significantly lower than other forces at the atomic level.
  • However, it has a longer range than the strong nuclear force, which acts over very short distances within the nucleus.
  • The weak force is also highly selective, specifically interacting only with certain subatomic particles called leptons, which include neutrinos and electrons.
  • The weak nuclear force is mediated by a family of particles called W and Z bosons.

White light

White light is the term for visible light that contains all wavelengths of the visible spectrum at equal intensities.

  • The sun emits white light because sunlight contains all the wavelengths of the visible spectrum in roughly equal proportions.
  • Light travelling through a vacuum or a medium is termed white light if it includes all wavelengths of visible light.
  • Light travelling through a vacuum or air isn’t visible to our eyes unless it interacts with something.
  • The term white light can have two meanings:
    • It can refer to a combination of all wavelengths of visible light traveling through space, regardless of observation.
    • What a person sees when all colours of the visible spectrum hit a white or neutral-coloured surface.
  • The human eye sees white when the wavelengths of light associated with the three primary colours – red, green, and blue (RGB) – are projected onto an achromatic surface.
  • White light appears as different colours to an observer when some wavelengths of light are reflected by an object’s surface while others are absorbed. Artificial light sources usually emit light with a varied distribution of wavelengths or intensities, so they don’t typically emit pure white light.
  • While there isn’t a single, distinct definition for white light, it’s fair to say that in any given situation:
    • White is the lightest possible colour.
    • White is an achromatic colour, which means a colour without hue, but with maximum saturation and brightness.
    • Colour constancy, the ability to perceive colours as relatively constant, even under changing lighting conditions, enables human observers to see very different whites as appearing the same.
Why do Light Bulbs Glow if Light is Invisible?
  • Incandescent light bulbs work by passing an electrical current through a thin tungsten filament which has high electrical resistance.
  • This resistance causes the filament’s electrons to vibrate and heat up. As the filament gets hot, it emits light.
  • The yellowish-white colour we see comes primarily from the heated tungsten surface itself.
  • Light bulbs, like most hot objects, also emit wavelengths of light that are outside the visible region of the electromagnetic spectrum.
  • These invisible wavelengths are typically infrared radiation, which we feel as heat. Additionally, a small portion of the light emitted might be ultraviolet, but these are blocked by the glass bulb.

Workflow

A workflow is a series of tasks arranged in a specific order to achieve a goal effectively and efficiently. By planning and organizing a workflow, you can ensure no important steps are missed and that the process runs smoothly. This can save time, reduce errors, and lead to consistent results.

  • A successful workflow requires careful assembly and organization of all resources beforehand so that they can be structured into a step-by-step procedure.
    • A typical colour management workflow might begin by ensuring that colours viewed through a camera viewfinder are captured and digitally recorded.
    • Image editing software such as Adobe CC might then be used to work through a decision-making process to ensure an image is fit for purpose.
    • When the workflow requires it, monitor calibration might be used to ensure that information is accurately displayed when viewed on screen.
    • A successful outcome is achieved when the final image accurately represents all decisions made during the editing process.
  • A workflow is a series of tasks arranged in a specific order to achieve a goal effectively and efficiently.
  • By planning and organizing a workflow, you can ensure no important steps are missed and that the process runs smoothly.
  • This can save time, reduce errors, and lead to consistent results.
  • A successful workflow requires careful assembly and organization of all resources beforehand so that they can be structured into a step-by-step procedure.
    • A typical colour management workflow might begin by ensuring that colours viewed through a camera viewfinder are captured and digitally recorded.
    • Image editing software such as Adobe CC might then be used to work through a decision-making process to ensure an image is fit for purpose.
    • A successful outcome is achieved when the final image accurately represents all decisions made during the editing process.