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mass

 
Dictionary: mass   (măs) pronunciation
 
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n.
  1. A unified body of matter with no specific shape: a mass of clay.
  2. A grouping of individual parts or elements that compose a unified body of unspecified size or quantity: “Take mankind in mass, and for the most part, they seem a mob of unnecessary duplicates” (Herman Melville).
  3. A large but nonspecific amount or number: a mass of bruises.
  4. A lump or aggregate of coherent material: a cancerous mass.
  5. The principal part; the majority: the mass of the continent.
  6. The physical volume or bulk of a solid body.
  7. (Abbr. m) Physics. A property of matter equal to the measure of an object's resistance to changes in either the speed or direction of its motion. The mass of an object is not dependent on gravity and therefore is different from but proportional to its weight.
  8. An area of unified light, shade, or color in a painting.
  9. Pharmacology. A thick, pasty mixture containing drugs from which pills are formed.
  10. masses The body of common people or people of low socioeconomic status: “Give me your tired, your poor,/Your huddled masses yearning to breathe free” (Emma Lazarus).
tr. & intr.v., massed, mass·ing, mass·es.

To gather or be gathered into a mass.

adj.
  1. Of, relating to, characteristic of, directed at, or attended by a large number of people: mass education; mass communication.
  2. Done or carried out on a large scale: mass production.
  3. Total; complete: The mass result is impressive.

[Middle English masse, from Old French, from Latin massa, from Greek māza, maza.]


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Sci-Tech Encyclopedia: Mass
 
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The quantitative or numerical measure of a body's inertia, that is, of its resistance to being accelerated.

Because it is often necessary to compare masses of such dissimilar bodies as a sample of sugar, a sample of air, an electron, and the Moon, it is necessary to define mass in terms of a property that not only is inherent and permanent but is also universal in that it is possessed by all known forms of matter. All matter possesses two properties, gravitation and inertia. The property of gravitation is that every material body attracts every other material body. The property of inertia is that every material body resists any attempt to change its motion. A body's motion is said to change if the body is accelerated, that is, if it increases or decreases its speed or changes the direction of its motion. Because of its inertia a body cannot be accelerated unless a force is exerted on it. The greater the inertia of a body, the less will be the acceleration produced by a given force. See also Gravitation; Inertia.

The present definition of mass is in terms of inertia. The masses of two bodies are compared by applying equal forces to the bodies and measuring their accelerations. For example, the two bodies may be allowed to collide. According to Newton's third law, each body will then experience an equally strong force. If there are no external forces, and if a1 and a2 are the measured accelerations of the two bodies, the ratio of the masses of the two bodies is by definition given by the equation \frac{m_1}{m_2}=\frac{a_2}{a_1}

This equation gives only ratios of masses; it is therefore necessary to designate the mass of some one body as the standard mass to which the masses of all other bodies can be compared. The body that has been chosen for this purpose is a cylinder of platinum-iridium alloy. It is known as the international standard of mass; its mass is called 1 kilogram (kg), and it is kept at the International Bureau of Weights and Measures near Paris, France. Replicas of the standard mass, kept at various national laboratories, are periodically compared with this standard.

Einstein's special theory of relativity predicts that the inertia of a body should increase if the energy of the body increases. This prediction has been conclusively verified experimentally. It follows that the mass of a body will increase if, for example, the body gains speed (addition of kinetic energy), or its temperature rises (addition of heat energy), or the body is compressed (addition of elastic energy). See also Conservation of mass.

 
Thesaurus: mass
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noun

  1. A separate and distinct portion of matter: body, bulk, object. See matter.
  2. A quantity accumulated: accumulation, aggregation, amassment, assemblage, collection, congeries, cumulation, gathering. See collect/distribute.
  3. A group of things gathered haphazardly: agglomeration, bank1, cumulus, drift, heap, hill, mess, mound, mountain, pile, shock2, stack, tumble. See order/disorder.
  4. A great deal: abundance, mountain, much, plenty, profusion, wealth, world. Informal barrel, heap, lot, pack, peck2, pile. Regional power, sight. See big/small/amount.
  5. An enormous number of persons gathered together: crowd, crush, drove, flock, horde, mob, multitude, press, ruck1, swarm, throng. See big/small/amount, group.
  6. A very large number of things grouped together: army, cloud, crowd, drove, flock, horde, host, legion, mob, multitude, ruck1, score (used in plural), swarm, throng. See big/small/amount, group.
  7. The greatest part or portion: bulk, preponderance, preponderancy, weight. See big/small/amount.
  8. Great extent, amount, or dimension: amplitude, bulk, magnitude, size, volume (often used in plural). See big/small/amount.
  9. The common people. common (used in plural), commonality, commonalty, commoner (used in plural), crowd, hoi polloi, mob, pleb (used in plural), plebeian (used in plural), populace, public, ruck1, third estate. See over/under.

 
Britannica Concise Encyclopedia: mass
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Quantitative measure of inertia, or the resistance of a body to a change in motion. The greater the mass, the smaller is the change produced by an applied force. Unlike weight, the mass of an object remains constant regardless of its location. Thus, as a satellite moves away from the gravitational pull of the Earth, its weight decreases but its mass remains the same. In ordinary, classical chemical reactions, mass can be neither created nor destroyed. The sum of the masses of the reactants is always equal to the sum of the masses of the products. For example, the mass of wood and oxygen that disappears in combustion is equal to the mass of water vapour, carbon dioxide, smoke, and ash that appears. However, Albert Einstein's special theory of relativity shows that mass and energy are equivalent, so mass can be converted into energy and vice versa. Mass is converted into energy in nuclear fusion and nuclear fission. In these instances, conservation of mass is seen as a special case of a more general conservation of mass-energy. See also critical mass.

For more information on mass, visit Britannica.com.

 
Architecture and Landscaping: mass
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Body of coherent matter of relatively large bulk, a solid physical object, so applied to built forms, as in the mass of the building.

 
Columbia Encyclopedia: mass
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mass, in physics, the quantity of matter in a body regardless of its volume or of any forces acting on it. The term should not be confused with weight, which is the measure of the force of gravity (see gravitation) acting on a body. Under ordinary conditions the mass of a body can be considered to be constant; its weight, however, is not constant, since the force of gravity varies from place to place. There are two ways of referring to mass, depending on the law of physics defining it: gravitational mass and inertial mass. The gravitational mass of a body may be determined by comparing the body on a beam balance with a set of standard masses; in this way the gravitational factor is eliminated. The inertial mass of a body is a measure of the body's resistance to acceleration by some external force. One body has twice as much inertial mass as another body if it offers twice as much force in opposition to the same acceleration. All evidence seems to indicate that the gravitational and inertial masses of a body are equal, as demanded by Einstein's equivalence principle of relativity; so that at the same location equal (inertial) masses have equal weights. Because the numerical value for the mass of a body is the same anywhere in the world, it is used as a basis of reference for many physical measurements, such as density and heat capacity. According to the special theory of relativity, mass is not strictly constant but increases with the speed according to the formula m=m0/√1−v2/c2, where m0 is the rest mass of the body, v is its speed, and c is the speed of light in vacuum. This increase in mass, however, does not become appreciable until very great speeds are reached. The rest mass of a body is its mass at zero velocity. The special theory of relativity also leads to the Einstein mass-energy relation, E=mc2, where E is the energy, and m and c are the (relativistic) mass and the speed of light, respectively. Because of this equivalence of mass and energy, the law of conservation of energy was extended to include mass as a form of energy.

 
Science Dictionary: mass
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In physics, the property of matter that measures its resistance to acceleration. Roughly, the mass of an object is a measure of the number of atoms in it. The basic unit of measurement for mass is the kilogram. (See Newton's laws of motion; compare weight.)

 
Veterinary Dictionary: mass
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1. a lump or collection of cohering particles.
2. that characteristic of matter which gives it inertia.

  • m.–action ratios — the ratio of substrate to product, where the predominance of one, usually the substrate, over the other thermodynamically favors a particular direction for a reaction.
  • inner cell m. — an internal cluster of cells at the embryonic pole of the blastocyst which develops into the body of the embryo.
  • lean body m. — that part of the body including all its components except neutral storage lipid; in essence, the fat-free mass of the body.
  • m. medication — (or immunization, or treatment, or prophylaxis, or testing, or screening) application of the procedure to all of the animals in the population, which may be as small as a herd or as large as a national herd. This sort of strategy has been used extensively and for many years in the control of diseases of animals, and has been the principal reason for the dramatic virtual eradication of the major plagues in many countries. The unintelligent extension of the strategy to the control of wastage caused by endemic disease has contributed most to the problem of residues of antibacterial drugs in the human food chain. See also mass medication.
  • m. number — the number used to express the mass of a nucleus, being the total number of nucleons, protons and neutrons in the nucleus of an atom or nuclide; symbol A.
  • m. reflex — reflex actions by all the body parts controlled by the part of the spinal cord which has been injured.
  • thalamic intermediate m. — see interthalamic adhesion.
 
Military Dictionary: mass
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(DOD, NATO) 1. The concentration of combat power. 2. The military formation in which units are spaced at less than the normal distances and intervals.

 
Word Tutor: mass
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pronunciation

IN BRIEF: A body of matter.

pronunciation Often when looking at a mass of things for sale, he would say to himself, 'How many things I have no need of! — Socrates, (469-399 BC), Greek philosopher, mentor to Plato.

 
Wikipedia: Mass
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For different units of mass, see Orders of magnitude (mass).
For other uses of "Mass", see Mass (disambiguation).
Sir Isaac Newton (1642-1727)

Mass (from Greek: Μάζα) is a concept used in the physical sciences to explain a number of observable behaviors, and in everyday usage, it is common to identify mass with those resulting behaviors. In particular, mass is commonly identified with weight. But according to our modern scientific understanding, the weight of an object results from the interaction of its mass with a gravitational field, so while mass is part of the explanation of weight, it is not the complete explanation.

For example, a mail carrier lifting a heavy package on earth may associate the heaviness (weight) of the package with the mass of its contents. This is a reasonable association for objects on earth. However, if the same package were on the moon, it would weigh much less and would be easy to lift. Therefore, the mass of a package is only part of the reason that the package is difficult to lift on earth. The complete reason involves the interaction of the package’s mass with the gravity of the earth.

Also, a groundskeeper encountering two large rocks may associate the size of the rocks with their respective masses. And from this association the groundskeeper may expect the larger rock to be heavier and more difficult to move. However, if the larger rock were composed of pumice and the smaller of granite, then the smaller rock may in fact be much heavier. Mass is part of the explanation of an object’s size but not the complete explanation. The complete explanation involves mass, structure, and composition.

The human body is equipped with physical senses through which one can experience many of the effects associated with mass. One can visually observe an object to determine its size, lift it to feel its weight, and push it to feel the force of its inertial resistance to changing motion. These human experiences are all part of our modern understanding of mass, but none completely epitomizes the abstract concept of mass. The abstract concept did not come from a specific type of human experience. Rather, it came from a synthesis of many different types of human experience.

Humans throughout history have observed the inertial and gravitational effects of mass. They have also observed the planets moving through the night sky under the influence of the sun’s gravity, and they have observed objects falling to the earth under the influence of the earth’s gravity. Since these effects were all part of human existence, humans have always had an intuitive understanding of these physical phenomena. This intuitive understanding, however, only recently evolved into the modern abstract concept of mass.

The modern concept was introduced in, and is central to, Isaac Newton’s explanation of gravitation and inertia. Prior to Newton’s time, the various gravitational and inertial phenomena were viewed as distinct and potentially unrelated. However, Isaac Newton united these phenomena by asserting that they all stemmed from a single underlying property called mass. Since Newton’s time, this abstract concept of mass has grown to include explanations for both quantum and relativistic effects. (See the following section entitled “Summary of concepts of mass” for a brief summery of mass related phenomena)

Contents

Units of mass

The primary instrument used to measure mass is the scale or balance scale. In the SI system of units, mass is measured in kilograms, kg. Many other units of mass are also employed, such as:

Outside the SI system, a variety of different mass units are used, depending on context, such as the:

In normal situations, the weight of an object is proportional to its mass, which usually makes it unproblematic to use the same unit for both concepts. However, the distinction between mass and weight becomes important for measurements with a precision better than a few percent (due to slight differences in the strength of the Earth's gravitational field at different places), and for places far from the surface of the Earth, such as in space or on other planets.

Because of the relativistic connection between mass and energy (see mass in special relativity), it is possible to use any unit of energy as a unit of mass instead. For example, the eV energy unit is normally used as a unit of mass (roughly 1.783×10−36 kg) in particle physics. A mass can sometimes also be expressed in terms of length. Here one identifies the mass of a particle with its inverse Compton wavelength (1 cm−13.52×10−41 kg).

Summary of concepts of mass

The above diagram illustrates five interrelated properties of mass together with the proportionality constants that relate these properties. Every sample of mass is believed to exhibit all five properties, however, due to extremely large proportionality constants, it is generally impossible to verify more than two or three properties for a specific sample of mass.
  • The Schwarzschild radius (rs) represents the ability of mass to cause curvature in space and time.
  • The standard gravitational parameter (μ) represents the ability of a massive body to exert Newtonian gravitational forces on other bodies.
  • Inertial mass (m) represents the Newtonian response of mass to forces.
  • Rest energy (E0) represents the ability of mass to be converted into other forms of energy.
  • The Compton wavelength (λ) represents the quantum response of mass to local geometry.

In physical science, one may distinguish conceptually between at least seven attributes of mass, or seven physical phenomena that can be explained using the concept of mass:[1]

  • Inertial mass is a measure of an object's resistance to changing its state of motion when a force is applied. It is determined by applying a force to an object and measuring the acceleration that results from that force. An object with small inertial mass will accelerate more than an object with large inertial mass when acted upon by the same force. One says the body of greater mass has greater inertia.
  • The amount of matter in certain types of samples can be exactly determined through electrodeposition or other precise processes. The mass of an exact sample is determined in part by the number and type of atoms or molecules it contains, and in part by the energy involved in binding it together (which contributes a negative "missing mass," or mass deficit).
  • Active gravitational mass is a measure of the strength of an object’s gravitational flux (gravitational flux is equal to the surface integral of gravitational field over an inclosing surface). Gravitational field can be measured by allowing a small ‘test object’ to freely fall and measuring its free-fall acceleration. For example, an object in free-fall near the Moon will experience less gravitational field, and hence accelerate slower than the same object would if it were in free-fall near the earth. The gravitational field near the Moon is weaker because the Moon has less active gravitational mass.
  • Passive gravitational mass is a measure of the strength of an object's interaction with a gravitational field. Passive gravitational mass is determined by dividing an object’s weight by its free-fall acceleration. Two objects within the same gravitational field will experience the same acceleration, however, the object with a smaller passive gravitational mass will experience a smaller force (less weight) than the object with a larger passive gravitational mass.
  • Energy also has mass according to the principle of mass–energy equivalence. This equivalence is exemplified in a large number of physical processes including pair production, nuclear fusion, and the gravitational bending of light. Pair production and nuclear fusion are processes through which measurable amounts of mass and energy are converted into each other. In the gravitational bending of light, photons of pure energy are shown to exhibit a behavior similar to passive gravitational mass.
  • Curvature of spacetime is a relativistic manifestation of the existence of mass. Curvature is extremely weak and difficult to measure. For this reason, curvature wasn’t discovered until after it was predicted by Einstein’s theory of general relativity. Extremely precise atomic clocks on the surface of the earth, for example, are found to measure less time (run slower) than similar clocks in space. This difference in elapsed time is a form of curvature called gravitational time dilation. Other forms of curvature have been measured using the Gravity Probe B satellite.

Inertial and gravitational mass

Although inertial mass, passive gravitational mass and active gravitational mass are conceptually distinct, no experiment has ever unambiguously demonstrated any difference between them. In classical mechanics, Newton's third law implies that active and passive gravitational mass must always be identical (or at least proportional), but the classical theory offers no compelling reason why the gravitational mass has to equal the inertial mass. That it does is merely an empirical fact.

Albert Einstein developed his general theory of relativity starting from the assumption that this correspondence between inertial and (passive) gravitational mass is not accidental: that no experiment will ever detect a difference between them (the weak version of the equivalence principle). However, in the resulting theory gravitation is not a force and thus not subject to Newton's third law, so "the equality of inertial and active gravitational mass [...] remains as puzzling as ever".[2]

Inertial mass

This section uses mathematical equations involving differential calculus.

Inertial mass is the mass of an object measured by its resistance to acceleration.

To understand what the inertial mass of a body is, one begins with classical mechanics and Newton's Laws of Motion. Later on, we will see how our classical definition of mass must be altered if we take into consideration the theory of special relativity, which is more accurate than classical mechanics. However, the implications of special relativity will not change the meaning of "mass" in any essential way.

According to Newton's second law, we say that a body has a mass m if, at any instant of time, it obeys the equation of motion

F = \frac{\mathrm{d}}{\mathrm{d}t} (mv)

where f is the force acting on the body and v is its velocity. For the moment, we will put aside the question of what "force acting on the body" actually means.

Now, suppose that the mass of the body in question is a constant. This assumption, known as the conservation of mass, rests on the ideas that (i) mass is a measure of the amount of matter contained in a body, and (ii) matter can never be created or destroyed, only split up or recombined. These are very reasonable assumptions for everyday objects, though, as we will see, matter can indeed be created or destroyed if "matter" is defined strictly as certain kinds of particles and not others. However (see below) in theory of relativity all mathematically definably definitions of mass are separately conserved over time within closed systems (where no particles or energy are allowed into or out of the system), because energy is conserved over time in such systems, and mass and energy in relativity always occur in exact association.

When the mass of a body is constant (neither mass nor energy are being allowed in or out of the body), Newton's second law becomes

F = m \frac{\mathrm{d}v}{\mathrm{d}t} = m a

where a denotes the acceleration of the body.

This equation illustrates how mass relates to the inertia of a body. Consider two objects with different masses. If we apply an identical force to each, the object with a bigger mass will experience a smaller acceleration, and the object with a smaller mass will experience a bigger acceleration. We might say that the larger mass exerts a greater "resistance" to changing its state of motion in response to the force.

However, this notion of applying "identical" forces to different objects brings us back to the fact that we have not really defined what a force is. We can sidestep this difficulty with the help of Newton's third law, which states that if one object exerts a force on a second object, it will experience an equal and opposite force. To be precise, suppose we have two objects A and B, with constant inertial masses mA and mB. We isolate the two objects from all other physical influences, so that the only forces present are the force exerted on A by B, which we denote fAB, and the force exerted on B by A, which we denote fBA. As we have seen, Newton's second law states that

f_{AB} = m_B a_B \, and f_{BA} = m_A a_A \,

where aA and aB are the accelerations of A and B respectively. Suppose that these accelerations are non-zero, so that the forces between the two objects are non-zero. This occurs, for example, if the two objects are in the process of colliding with one another. Newton's third law then states that

f_{AB} = - f_{BA}. \,

Substituting this into the previous equations, we obtain

m_A = - \frac{a_B}{a_A} \, m_B.

Note that our requirement that aA be non-zero ensures that the fraction is well-defined.

This is, in principle, how we would measure the inertial mass of an object. We choose a "reference" object and define its mass mB as (say) 1 kilogram. Then we can measure the mass of any other object in the universe by colliding it with the reference object and measuring the accelerations.

Gravitational mass

Gravitational mass is the mass of an object measured using the effect of a gravitational field on the object.

The concept of gravitational mass rests on Newton's law of gravitation. Let us suppose we have two objects A and B, separated by a distance |rAB|. The law of gravitation states that if A and B have gravitational masses MA and MB respectively, then each object exerts a gravitational force on the other, of magnitude

|f| = {G M_A M_B \over |r_{AB}|^2}

where G is the universal gravitational constant. The above statement may be reformulated in the following way: if g is the acceleration of a reference mass at a given location in a gravitational field, then the gravitational force on an object with gravitational mass M is

f = Mg \ .

This is the basis by which masses are determined by weighing. In simple bathroom scales, for example, the force f is proportional to the displacement of the spring beneath the weighing pan (see Hooke's law), and the scales are calibrated to take g into account, allowing the mass M to be read off. Note that a balance (see the subheading within Weighing scale) as used in the laboratory or the health club measures gravitational mass; only the spring scale measures weight.

Equivalence of inertial and gravitational masses

The equivalence of inertial and gravitational masses is sometimes referred to as the Galilean equivalence principle or weak equivalence principle. The most important consequence of this equivalence principle applies to freely falling objects. Suppose we have an object with inertial and gravitational masses m and M respectively. If the only force acting on the object comes from a gravitational field g, combining Newton's second law and the gravitational law yields the acceleration

a = \frac{M}{m} g.

This says that the ratio of gravitational to inertial mass of any object is equal to some constant K if and only if all objects fall at the same rate in a given gravitational field. This phenomenon is referred to as the 'universality of free-fall'. (In addition, the constant K can be taken to be 1 by defining our units appropriately.)

The first experiments demonstrating the universality of free-fall were conducted by Galileo. It is commonly stated that Galileo obtained his results by dropping objects from the Leaning Tower of Pisa, but this is most likely apocryphal; actually, he performed his experiments with balls rolling down inclined planes. Increasingly precise experiments have been performed, such as those performed by Loránd Eötvös, using the torsion balance pendulum, in 1889. As of 2008, no deviation from universality, and thus from Galilean equivalence, has ever been found, at least to the accuracy 10-12. More precise experimental efforts are still being carried out.

The universality of free-fall only applies to systems in which gravity is the only acting force. All other forces, especially friction and air resistance, must be absent or at least negligible. For example, if a hammer and a feather are dropped from the same height through the air on Earth, the feather will take much longer to reach the ground; the feather is not really in free-fall because the force of air resistance upwards against the feather is comparable to the downward force of gravity. On the other hand, if the experiment is performed in a vacuum, in which there is no air resistance, the hammer and the feather should hit the ground at exactly the same time (assuming the acceleration of both objects towards each other, and of the ground towards both objects, for its own part, is negligible). This can easily be done in a high school laboratory by dropping the objects in transparent tubes that have the air removed with a vacuum pump. It is even more dramatic when done in an environment that naturally has a vacuum, as David Scott did on the surface of the Moon during Apollo 15.

A stronger version of the equivalence principle, known as the Einstein equivalence principle or the strong equivalence principle, lies at the heart of the general theory of relativity. Einstein's equivalence principle states that within sufficiently small regions of space-time, it is impossible to distinguish between a uniform acceleration and a uniform gravitational field. Thus, the theory postulates that inertial and gravitational masses are fundamentally the same thing.

Mass and energy in relativity

Main article: Mass in special relativity

The term mass in special relativity usually refers to the rest mass of the object, which is the Newtonian mass as measured by an observer moving along with the object. The invariant mass is another name for the rest mass of single particles. However, the more general invariant mass (calculated with a more complicated formula) may also be applied to systems of particles in relative motion, and because of this, is usually reserved for systems which consist of widely separated high-energy particles. The invariant mass of systems is the same for all observers and inertial frames, and cannot be destroyed, and is thus conserved, so long as the system is closed. In this case, "closure" implies that an idealized boundary is drawn around the system, and no mass/energy is allowed across it. In as much as energy is conserved in closed systems in relativity, the relativistic definition(s) of mass are quantities which are conserved also; they do not change over time, even as some types of particles are converted to others.

In bound systems, the binding energy must (often) be subtracted from the mass of the unbound system, simply because this energy has mass, and this mass is subtracted from the system when it is given off, at the time it is bound. Mass is not conserved in this process because the system is not closed during the binding process. A familiar example is the binding energy of atomic nuclei, which appears as other types of energy (such as gamma rays) when the nuclei are formed, and (after being given off) results in nuclides which have less mass than the free particles (nucleons) of which they are composed.

The term relativistic mass is also used, and this is the total quantity of energy in a body or system (divided by c2). The relativistic mass (of a body or system of bodies) includes a contribution from the kinetic energy of the body, and is larger the faster the body moves, so unlike the invariant mass, the relativistic mass depends on the observer's frame of reference. However, for given single frames of reference and for closed systems, the relativistic mass is also a conserved quantity.

Because the relativistic mass is proportional to the energy, it has gradually fallen into disuse among physicists.[3] There is disagreement over whether the concept remains pedagogically useful.[4][5]

For a discussion of mass in general relativity, see mass in general relativity.

Notes

  1. ^ W. Rindler (2006). op. cit.. Oxford: Oxford Univ. Press. p. 16; Section 1.12. ISBN 0198567316. http://books.google.com/books?id=MuuaG5HXOGEC&pg=PA112&dq=%22mass+energy+equivalence%22+date:2004-2010&lr=&as_brr=0&as_pt=ALLTYPES#PPA16,M1. 
  2. ^ W. Rindler (2006). op. cit.. Oxford: Oxford Univ. Press. p. 22; end of Section 1.14. ISBN 0198567316. http://books.google.com/books?id=MuuaG5HXOGEC&pg=PA112&dq=%22mass+energy+equivalence%22+date:2004-2010&lr=&as_brr=0&as_pt=ALLTYPES#PPA23,M1. 
  3. ^ G. Oas (2005). "On the Abuse and Use of Relativistic Mass". arΧiv: physics/0504110 [physics.ed-ph]. 
  4. ^ L.B. Okun (1989). "The Concept of Mass" ([dead link]Scholar search). Physics Today 42 (6): 31–36. doi:10.1063/1.881171. http://www.physicstoday.org/vol-42/iss-6/vol42no6p31_36.pdf. 
  5. ^ T. R. Sandin (1991). "In defense of relativistic mass". American Journal of Physics 59 (11): 1032. doi:10.1119/1.16642. http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=AJPIAS000059000011001032000001&idtype=cvips&gifs=yes. 

References

  • R.V. Eötvös et al., Ann. Phys. (Leipzig) 68 11 (1922)
  • E.F. Taylor, J.A. Wheeler (1992). Spacetime Physics. New York: W.H. Freeman. ISBN 0-7167-2327-1. 

External links


This entry is from Wikipedia, the leading user-contributed encyclopedia. It may not have been reviewed by professional editors (see full disclaimer)

 
Translations: Mass
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Dansk (Danish)
n. - masse, sammenklumpning, flertal, hovedpart
adj. - masse-
v. tr. - ophobe, samle
v. intr. - ophobes, samles

idioms:

  • a mass of    mængde, masse, mange
  • High Mass    (kirkelig) højmesse
  • midnight mass    midnatsmesse

n. - messe (kirkelig), altergang

Nederlands (Dutch)
(zich) verzamelen, (mensen)massa, mis, merendeel, grote hoeveelheid, betreffende de massa, massaal, totaal, meester

Français (French)
n. - masse (de), amas (de), foule, quantité (de), (Relig) messe, (Phys, Art) masse
adj. - de masse, en masse, massif, collectif
v. tr. - masser (des troupes)
v. intr. - se masser (en troupes), s'amonceler (des nuages)

idioms:

  • a mass of    une masse de
  • High Mass    grand-messe
  • in mass    en masse
  • in the mass    dans la masse
  • midnight Mass    messe de minuit

n. - (Relig) Messe

Deutsch (German)
n. - Masse (Teig), Menge (Sand, Fehler usw.), Anhäufung, Gesamtheit, Massivität, (Phys.) Masse
v. - sich versammeln, sich zusammenziehen, (sich) massieren, (sich) anhäufen
adj. - Massen..., Mess...

idioms:

  • a mass of    eine Unmenge
  • High Mass    Hochamt
  • in mass    in der Messe
  • in the mass    als Ganzes
  • midnight Mass    Mitternachtsmesse (bes. am 24.Dezember)

n. - (rk. Kirche) Messe

Ελληνική (Greek)
n. - (θεία) Λειτουργία, Ακολουθία, μάζα, μεγάλη ποσότητα ή πλήθος, όγκος, το μεγαλύτερο μέρος, η πλειοψηφία, (πληθ.) οι μάζες, ο πολύς λαός
v. - σχηματίζω μάζα, μαζεύω/-ομαι, συγκεντρώνω/-ομαι σε μάζες
adj. - μαζικός
abbr. - Μασαχουσέτη

idioms:

  • a mass of    όγκος, μάζα, πλήθος
  • High Mass    μεγάλη λειτουργία
  • midnight mass    (θρησκ.) μεσονύκτια λειτουργία/ακολουθία

Italiano (Italian)
ammassarsi, folla, messa, gran quantità

idioms:

  • a mass of    una massa di
  • midnight mass    messa di mezzanotte

Português (Portuguese)
n. - multidão (f), missa (f), massa (f)
v. - reunir-se, amontoar
adj. - em grande escala, em massa
abbr. - Massachusetts

idioms:

  • a mass of    grande quantidade
  • High Mass    Missa Solene (f)
  • midnight mass    Missa do Galo (f)

Русский (Russian)
масса, большинство, сосредоточение, месса, массовый, широкий, собирать в кучу, служить обедню

idioms:

  • a mass of    масса чего-то, множество
  • High Mass    торжественная месса
  • midnight mass    полночная месса

Español (Spanish)
n. - masa, multitud, gentío, muchedumbre, misa
adj. - de masa o masas, en gran escala
v. tr. - amasar, juntar, reunir en masa
v. intr. - juntarse en masa, amontonarse, reunirse

idioms:

  • a mass of    un montón de, la mar de, una gran cantidad de
  • High Mass    misa mayor
  • in mass    en masa
  • in the mass    en masa, en conjunto
  • midnight Mass    misa del gallo

n. - misa

Svenska (Swedish)
n. - mässa, massa, yta, massformering
v. - samla (ihop), koncentrera
adj. - hopsamlat
abbr. - Massachusetts

中文(简体)(Chinese (Simplified))
弥撒, 弥撒曲

块, 质量, 大多数, 群众的, 集中的, 大规模的, 使集合, 集中, 聚集

idioms:

  • a mass of    大量的
  • High Mass    大弥撒
  • midnight mass    心脏按摩

中文(繁體)(Chinese (Traditional))
n. - 彌撒, 彌撒曲

n. - 塊, 質量, 大多數
adj. - 群眾的, 集中的, 大規模的
v. tr. - 使集合, 集中
v. intr. - 聚集

idioms:

  • a mass of    大量的
  • High Mass    大彌撒
  • midnight mass    心臟按摩

한국어 (Korean)
n. - 거대한 덩어리, 많음, 대중, 부피
adj. - 많은 양의, 대중의
v. tr. - 거대한 덩어리로 만들다
v. intr. - 거대한 덩어리가 되다

idioms:

  • a mass of    다수[량]의, 대부분의

n. - (카톨릭의) 미사

日本語 (Japanese)
n. - 塊, 集まり, ミサ曲, 大衆, 労働者階級, 大部分, 質量, 大きさ, かさ
v. - 集める, ひと塊にする
adj. - 大量の, 大衆の

idioms:

  • a mass of    大きなかたまり, 多数の
  • mass media    マスメディア

العربيه (Arabic)
‏(الاسم) قداس, , جمهور, كتله (فعل) يتكتل (صفه) ضخم, واسع, ما يخص الجماهير (اختصار) جماعه من‏

עברית (Hebrew)
n. - ‮מיסה (תפילה), מוסיקה לתפילה, גוש, שפע, גוש חומר ללא צורה מסוימת (מסה), אוסף, כמות החומר בגוף, כמות רבה, המון, רוב, חלק עיקרי‬
adj. - ‮המוני, של המונים, בקנה-מידה גדול‬
v. tr. - ‮צבר, ריכז‬
v. intr. - ‮התרכז, התקבץ‬
n. - ‮טקס הסעודה האחרונה בייחוד בכנסיה הקתולית, התפילות בטקס זה‬

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Science Dictionary. The New Dictionary of Cultural Literacy, Third Edition Edited by E.D. Hirsch, Jr., Joseph F. Kett, and James Trefil. Copyright © 2002 by Houghton Mifflin Company. Published by Houghton Mifflin. All rights reserved.  Read more
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