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Symbols representing physical quantities, units, mathematical operations and relationships, astronomical bodies, constellations, and the Greek alphabet.
- Flow Regimes
Mach 0.5 corresponds to a flow speed that's half the speed...
- Gas Laws
or. P 1 V 1 = P 2 V 2 = constant. This correlation was...
- Light
Diffraction of laser light through a vertical opening of...
- Equations of Motion
Make velocity squared the subject and we're done. v 2 = v 0...
- Inductance
The unit of inductance is the henry, named after Joseph...
- Frames of Reference
Vertical frame of reference accelerations; g z (g) device,...
- Sound
Nodal lines are hyperbolas. Think about it, the definition...
- Lenz
When electromagnetic induction occurs (due to motion or...
- Flow Regimes
This is a list of common physical constants and variables, and their notations. Note that bold text indicates that the quantity is a vector. the inverse of the derivative. Elert, Glenn. "Special Symbols". The Physics Hypertextbook. Retrieved 4 August 2021. NIST (16 August 2023). "SI Units". www.nist.gov. NIST.
MeaningSi Unit Of Measuretesla meter (T⋅m)unitlessIn this glossary, key symbols and notation are briefly defined. This free textbook is an OpenStax resource written to increase student access to high-quality, peer-reviewed learning materials.
Mar 12, 2024 · In this glossary, key symbols and notation are briefly defined.
- Overview
- Early concepts
gravity, in mechanics, the universal force of attraction acting between all matter. It is by far the weakest known force in nature and thus plays no role in determining the internal properties of everyday matter. On the other hand, through its long reach and universal action, it controls the trajectories of bodies in the solar system and elsewhere in the universe and the structures and evolution of stars, galaxies, and the whole cosmos. On Earth all bodies have a weight, or downward force of gravity, proportional to their mass, which Earth’s mass exerts on them. Gravity is measured by the acceleration that it gives to freely falling objects. At Earth’s surface the acceleration of gravity is about 9.8 metres (32 feet) per second per second. Thus, for every second an object is in free fall, its speed increases by about 9.8 metres per second. At the surface of the Moon the acceleration of a freely falling body is about 1.6 metres per second per second.
The works of Isaac Newton and Albert Einstein dominate the development of gravitational theory. Newton’s classical theory of gravitational force held sway from his Principia, published in 1687, until Einstein’s work in the early 20th century. Newton’s theory is sufficient even today for all but the most precise applications. Einstein’s theory of general relativity predicts only minute quantitative differences from the Newtonian theory except in a few special cases. The major significance of Einstein’s theory is its radical conceptual departure from classical theory and its implications for further growth in physical thought.
Newton argued that the movements of celestial bodies and the free fall of objects on Earth are determined by the same force. The classical Greek philosophers, on the other hand, did not consider the celestial bodies to be affected by gravity, because the bodies were observed to follow perpetually repeating nondescending trajectories in the sky. Thus, Aristotle considered that each heavenly body followed a particular “natural” motion, unaffected by external causes or agents. Aristotle also believed that massive earthly objects possess a natural tendency to move toward Earth’s centre. Those Aristotelian concepts prevailed for centuries along with two others: that a body moving at constant speed requires a continuous force acting on it and that force must be applied by contact rather than interaction at a distance. These ideas were generally held until the 16th and early 17th centuries, thereby impeding an understanding of the true principles of motion and precluding the development of ideas about universal gravitation. This impasse began to change with several scientific contributions to the problem of earthly and celestial motion, which in turn set the stage for Newton’s later gravitational theory.
Britannica Quiz
All About Astronomy
The 17th-century German astronomer Johannes Kepler accepted the argument of Nicolaus Copernicus (which goes back to Aristarchus of Samos) that the planets orbit the Sun, not Earth. Using the improved measurements of planetary movements made by the Danish astronomer Tycho Brahe during the 16th century, Kepler described the planetary orbits with simple geometric and arithmetic relations. Kepler’s three quantitative laws of planetary motion are:
1.The planets describe elliptic orbits, of which the Sun occupies one focus (a focus is one of two points inside an ellipse; any ray coming from one of them bounces off a side of the ellipse and goes through the other focus).
2.The line joining a planet to the Sun sweeps out equal areas in equal times.
In this glossary, key symbols and notation are briefly defined.
Various notations and symbols are used to denote different quantities in Physics. The article provides a list of commonly used symbols in physics with their SI units.
