Glossary

5.1 Derivation and application of Lorentz transformations

4 min readaugust 7, 2024

are the mathematical heart of special relativity. They describe how space and time coordinates change between different reference frames moving at constant velocities relative to each other.

These transformations lead to mind-bending effects like and . They also reveal the , showing that the order of events can differ depending on your frame of reference.

Lorentz Transformations

Lorentz Factor and Relativistic Effects

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  • (γ\gamma) depends on the relative velocity between two reference frames
    • Defined as γ=11v2c2\gamma = \frac{1}{\sqrt{1-\frac{v^2}{c^2}}}, where vv is the relative velocity and cc is the speed of light
    • Approaches infinity as the relative velocity approaches the speed of light
  • Time dilation occurs when an observer in one reference frame measures a longer time interval than an observer in another reference frame
    • (τ\tau) is the time measured by a clock in its own rest frame
    • Dilated time (tt) is related to proper time by t=γτt = \gamma \tau
    • Example: Muons created in Earth's upper atmosphere have a longer lifetime from Earth's reference frame due to time dilation
  • Length contraction happens when an object appears shorter along the direction of motion to an observer in a different reference frame
    • (L0L_0) is the length of an object in its own rest frame
    • Contracted length (LL) is related to proper length by L=L0γL = \frac{L_0}{\gamma}
    • Example: A spacecraft traveling at high velocity would appear shorter to a stationary observer

Relativity of Simultaneity

  • Relativity of simultaneity states that events that are simultaneous in one reference frame may not be simultaneous in another
  • The order of events can differ between reference frames if the events are separated by a space-like interval
    • Space-like interval: (Δs)2=(Δx)2c2(Δt)2>0(\Delta s)^2 = (\Delta x)^2 - c^2(\Delta t)^2 > 0
  • Example: Two lightning strikes equidistant from an observer on a moving train may appear simultaneous to the observer on the train but not to an observer on the platform

Proper Measurements

Proper Time and Length

  • Proper time (τ\tau) is the time measured by a clock between two events that occur at the same location in the clock's rest frame
    • Proper time is always the shortest time interval between two events as measured by any clock
  • Proper length (L0L_0) is the length of an object as measured in its own rest frame
    • Proper length is always the longest length of an object as measured by any observer

Invariant Interval

  • The (Δs\Delta s) is a combination of the spatial and temporal separations between two events that remains constant in all reference frames
    • Defined as (Δs)2=c2(Δt)2(Δx)2(\Delta s)^2 = c^2(\Delta t)^2 - (\Delta x)^2
    • Can be classified as space-like ((Δs)2>0(\Delta s)^2 > 0), time-like ((Δs)2<0(\Delta s)^2 < 0), or light-like ((Δs)2=0(\Delta s)^2 = 0)
  • The proper time between two events is related to the invariant interval by τ=(Δs)2c\tau = \frac{\sqrt{-(\Delta s)^2}}{c} for time-like intervals
  • Example: The invariant interval between two events on a photon's world line is always zero (light-like interval)

Relativistic Velocity

Velocity Addition Formula

  • The relativistic combines velocities in different reference frames
    • For velocities uu and vv in the xx-direction, the combined velocity ww is given by w=u+v1+uvc2w = \frac{u + v}{1 + \frac{uv}{c^2}}
    • Velocities do not simply add linearly as they do in classical mechanics
  • The formula ensures that the combined velocity never exceeds the speed of light
    • As one velocity approaches cc, the combined velocity approaches cc regardless of the other velocity
  • Example: If a spacecraft is traveling at 0.8cc relative to Earth and fires a missile at 0.6cc relative to the spacecraft, the missile's velocity relative to Earth is 0.8c+0.6c1+(0.8c)(0.6c)c20.94c\frac{0.8c + 0.6c}{1 + \frac{(0.8c)(0.6c)}{c^2}} \approx 0.94c

Rapidity

  • (ϕ\phi) is a measure of the relative velocity between two reference frames that simplifies Lorentz transformations
    • Defined as ϕ=tanh1(vc)\phi = \tanh^{-1}(\frac{v}{c}), where vv is the relative velocity and cc is the speed of light
    • Lorentz factor can be expressed as γ=cosh(ϕ)\gamma = \cosh(\phi)
  • Rapidities add linearly, unlike velocities
    • For two reference frames with rapidities ϕ1\phi_1 and ϕ2\phi_2, the combined rapidity is simply ϕ1+ϕ2\phi_1 + \phi_2
  • Example: If frame B has a rapidity of 0.8 relative to frame A, and frame C has a rapidity of 0.6 relative to frame B, then frame C has a rapidity of 1.4 relative to frame A

Key Terms to Review (21)

Albert Einstein: Albert Einstein was a theoretical physicist best known for developing the theories of special relativity and general relativity, which revolutionized our understanding of space, time, and gravity. His groundbreaking work laid the foundation for modern physics and provided insights that reshaped concepts such as simultaneity, the nature of light, and the relationship between mass and energy.
Energy-Momentum Relation: The energy-momentum relation is a fundamental equation in physics that connects an object's total energy, momentum, and mass. It is often expressed as $$E^2 = (pc)^2 + (m_0c^2)^2$$, where 'E' is the total energy, 'p' is the momentum, 'c' is the speed of light, and 'm_0' is the rest mass. This relation highlights how energy and momentum are conserved in relativistic processes, which are described by Lorentz transformations, allowing for calculations in systems moving at significant fractions of the speed of light.
Gps technology: GPS technology, or Global Positioning System technology, is a satellite-based navigation system that allows users to determine their precise location anywhere on Earth. It relies on signals from a network of satellites to calculate positions and is essential for applications ranging from personal navigation to scientific research. The functioning of GPS is deeply intertwined with concepts like relativistic spatial measurements and the constancy of the speed of light, as well as effects like gravitational redshift, which can influence satellite signals.
Hendrik Lorentz: Hendrik Lorentz was a Dutch physicist best known for his contributions to the development of the theory of relativity and the formulation of the Lorentz transformations. His work laid crucial groundwork that influenced Albert Einstein's formulation of special relativity, particularly through his exploration of the behavior of moving bodies and electromagnetic phenomena.
Inertial Reference Frame: An inertial reference frame is a viewpoint in which an object not subjected to external forces moves at a constant velocity, including remaining at rest. This concept is crucial for understanding the principle of relativity, which states that the laws of physics are the same in all inertial frames. Recognizing inertial reference frames helps in analyzing motion and understanding how observers moving at different velocities perceive time and space.
Invariant Interval: The invariant interval is a fundamental quantity in the theory of relativity that measures the separation between two events in spacetime, remaining constant for all observers regardless of their relative motion. This interval combines both spatial and temporal distances, encapsulated in the formula $$s^2 = c^2 t^2 - x^2$$, ensuring that it retains the same value in all inertial frames. The concept is crucial for understanding relativistic effects and underpins many key principles in modern physics.
Length Contraction: Length contraction is a phenomenon predicted by the theory of relativity, stating that an object in motion is measured to be shorter along the direction of its motion relative to a stationary observer. This effect becomes significant at speeds approaching the speed of light and highlights the differences between classical and relativistic physics.
Lorentz Factor: The Lorentz factor is a mathematical term that arises in the theory of relativity, represented as $$ rac{1}{ ext{sqrt}(1 - rac{v^2}{c^2})}$$, where $$v$$ is the velocity of an object and $$c$$ is the speed of light. It quantifies how much time, length, and relativistic mass increase as an object approaches the speed of light. Understanding the Lorentz factor is crucial for grasping the effects of time dilation, length contraction, and relativistic measurements that occur in high-speed scenarios.
Lorentz Transformation Equations: The Lorentz transformation equations are a set of mathematical formulas that relate the space and time coordinates of events as observed in different inertial reference frames moving at constant velocities relative to each other. These equations are essential in understanding how measurements of time and space change for observers in relative motion, fundamentally altering our perception of simultaneity, length, and time intervals as described in the theory of special relativity.
Lorentz transformations: Lorentz transformations are mathematical equations that describe how the measurements of time and space change for observers in different inertial frames of reference, particularly those moving relative to each other at significant fractions of the speed of light. These transformations are central to the theory of relativity, linking the concepts of simultaneity, length contraction, and time dilation, which are crucial for understanding relativistic physics.
Mass-energy equivalence: Mass-energy equivalence is the principle that mass and energy are interchangeable; they are different forms of the same thing. This concept is famously encapsulated in the equation $$E = mc^2$$, which shows that energy (E) is equal to mass (m) multiplied by the speed of light (c) squared. This relationship implies that a small amount of mass can be converted into a large amount of energy, connecting the fundamental concepts of energy, mass, and their roles in physical processes.
Non-inertial reference frame: A non-inertial reference frame is a frame of reference that is undergoing acceleration, causing the laws of physics to appear different than they do in inertial frames. In these frames, observers may experience fictitious forces, such as centrifugal force or Coriolis force, which do not arise from any physical interaction but instead result from the acceleration of the frame itself. Understanding non-inertial frames is essential for applying Lorentz transformations, as they provide insight into how motion and forces are perceived differently based on an observer's state of motion.
Particle physics experiments: Particle physics experiments are investigations designed to study the fundamental particles of the universe and the forces that govern their interactions. These experiments often involve high-energy collisions of particles, allowing scientists to observe phenomena like time dilation and to verify the principles outlined in theories such as the Lorentz transformations. The results from these experiments provide crucial insights into the behavior of matter and energy at subatomic scales.
Proper Length: Proper length is the longest length of an object measured in the reference frame where the object is at rest. This concept is crucial in understanding how lengths are perceived differently by observers in relative motion, especially in the context of length contraction, where moving objects appear shorter to a stationary observer. Proper length serves as a baseline for comparing spatial measurements across different frames of reference, revealing the impact of relativistic effects and the nature of space-time.
Proper Time: Proper time is the time interval measured by a clock that is at rest relative to the event being timed, making it the longest time interval between two events when compared to observers in different frames of reference. This concept highlights how time can vary for different observers due to their relative motion and gravitational influences, influencing various phenomena including time dilation, simultaneity, and energy relationships in relativistic contexts.
Rapidity: Rapidity is a concept in special relativity that represents a way to express velocity in a linear fashion, defined mathematically as the hyperbolic tangent of the velocity divided by the speed of light. This term is especially useful because it simplifies the calculations involving relativistic effects, allowing for straightforward addition of velocities. Unlike classical velocity, rapidity remains additive even when dealing with relativistic speeds, making it an essential concept for understanding Lorentz transformations.
Relativistic velocity: Relativistic velocity refers to the velocity of an object as observed from a particular reference frame, especially when the object's speed approaches the speed of light. This concept is crucial for understanding how time, length, and simultaneity change for objects in motion at high speeds, which is fundamental in deriving and applying Lorentz transformations.
Relativity of simultaneity: The relativity of simultaneity is a concept in special relativity that states that events that are simultaneous in one frame of reference may not be simultaneous in another frame moving relative to the first. This idea challenges our intuitive understanding of time, emphasizing that the perception of when events occur depends on the observer's state of motion.
Time dilation: Time dilation is a phenomenon predicted by the theory of relativity, where time is observed to pass at different rates for observers in different frames of reference. This effect becomes significant at high velocities or in strong gravitational fields, leading to consequences such as the differences in aging between twins and the way we perceive simultaneous events.
Twin paradox: The twin paradox is a thought experiment in special relativity where one twin travels at a significant fraction of the speed of light while the other remains stationary, leading to different aging experiences for the two twins when they reunite. This situation highlights the effects of time dilation and the relativity of simultaneity, showcasing how motion affects time passage differently for observers in relative motion.
Velocity Addition Formula: The velocity addition formula is a crucial equation in special relativity that describes how to combine velocities of objects moving at significant fractions of the speed of light. It addresses the limitations of classical mechanics by showing that the sum of velocities is not linear when approaching light speed, instead leading to a more complex relationship described by this formula. Understanding this concept helps explain phenomena such as relativistic effects and paradoxes, connecting it to various thought experiments and the transformation equations in relativity.
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