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1 short ton = 0.907184739999998 ton (metric) [t]
Initial value
Converted value
kilogram gram exagram petagram teragram gigagram megagram hectogram decagram decigram centigram milligram microgram nanogram picogram femtogram attogram dalton, atomic mass unit kilogram-force square. sec./meter kilopound kilopound (kip) slug pound-force square. sec/foot pound troy pound ounce troy ounce metric ounce short ton long (English) ton assay ton (US) assay ton (Imperial) ton (metric) kiloton (metric) quintal (metric) quintal American quintal British quarter (US) quarter (British) stone (USA) stone (British) ton pennyweight scruple carat gran gamma talent (Dr. Israel) mina (Dr. Israel) shekel (Dr. Israel) bekan (Dr. Israel) gera (Dr. Israel) talent (Ancient Greece) mina (Ancient Greece) tetradrachm (Ancient Greece) didrachm (Ancient Greece) drachma (Ancient Greece) denarius (Ancient Rome) ass (Ancient Rome) codrant (Ancient Rome) lepton ( Dr. Rome) Planck mass atomic mass unit rest mass of an electron rest mass of a muon proton mass neutron mass deuteron mass mass of the Earth mass of the Sun Berkovets pud Pound lot spool share quintal livre
Thermal efficiency and fuel efficiency
More about mass
General information
Mass is the property of physical bodies to resist acceleration. Mass, unlike weight, does not change depending on environment and does not depend on the gravitational force of the planet on which this body is located. Mass m determined using Newton's second law, according to the formula: F = ma, Where F- this is strength, and a- acceleration.
Mass and weight
The word “weight” is often used in everyday life when people talk about mass. In physics, weight, in contrast to mass, is a force acting on a body due to the attraction between bodies and planets. Weight can also be calculated using Newton's second law: P= mg, Where m is the mass, and g- free fall acceleration. This acceleration occurs due to the gravitational force of the planet near which the body is located, and its magnitude also depends on this force. The acceleration of free fall on Earth is 9.80665 meters per second, and on the Moon it is approximately six times less - 1.63 meters per second. Thus, a body weighing one kilogram weighs 9.8 newtons on Earth and 1.63 newtons on the Moon.
Gravitational mass
Gravitational mass shows what gravitational force acts on a body (passive mass) and what gravitational force the body acts on other bodies (active mass). When increasing active gravitational mass body, its force of attraction also increases. It is this force that controls the movement and location of stars, planets and other astronomical objects in the universe. Tides are also caused by the gravitational forces of the Earth and Moon.
With increase passive gravitational mass the force with which the gravitational fields of other bodies act on this body also increases.
Inert mass
Inertial mass is the property of a body to resist movement. It is precisely because a body has mass that a certain force must be applied to move the body from its place or change the direction or speed of its movement. The greater the inertial mass, the greater the force required to achieve this. Mass in Newton's second law is precisely inertial mass. The gravitational and inertial masses are equal in magnitude.
Mass and relativity
According to the theory of relativity, gravitating mass changes the curvature of the space-time continuum. The greater the mass of a body, the stronger the curvature around this body, therefore, near bodies of large mass, such as stars, the trajectory of light rays is bent. This effect in astronomy is called gravitational lenses. On the contrary, far from large astronomical objects (massive stars or their clusters called galaxies), the movement of light rays is linear.
The main postulate of the theory of relativity is the postulate that the speed of propagation of light is finite. Several interesting consequences follow from this. Firstly, one can imagine the existence of objects with such a large mass that the second cosmic velocity of such a body will be equal to the speed of light, i.e. no information from this object will be able to reach the outside world. Such space objects general theory relativity are called “black holes” and their existence has been experimentally proven by scientists. Secondly, when an object moves at near-light speed, its inertial mass increases so much that local time inside the object slows down compared to time. measured by stationary clocks on Earth. This paradox is known as the "twin paradox": one of them is sent to space flight at near-light speed, the other remains on Earth. Upon returning from the flight twenty years later, it turns out that the twin astronaut is biologically younger than his brother!
Units
Kilogram
In the SI system, mass is expressed in kilograms. The kilogram is determined based on the exact numerical value of Planck's constant h, equal to 6.62607015×10⁻³⁴, expressed in J s, which is equal to kg m² s⁻¹, with the second and meter being determined by exact values c and Δ ν Cs. The mass of one liter of water can be approximately considered equal to one kilogram. The derivatives of kilogram, gram (1/1000 of a kilogram) and ton (1000 kilograms) are not SI units, but are widely used.
Electron-volt
Electronvolt is a unit for measuring energy. It is usually used in the theory of relativity, and energy is calculated using the formula E=mc², where E- this is energy, m- mass, and c- speed of light. According to the principle of equivalence of mass and energy, the electronvolt is also a unit of mass in the system of natural units, where c is equal to unity, which means mass equals energy. Electrovolts are mainly used in nuclear and atomic physics.
Atomic mass unit
Atomic mass unit ( A. e.m.) is intended for masses of molecules, atoms, and other particles. One a. e.m. is equal to 1/12 the mass of a carbon nuclide atom, ¹²C. This is approximately 1.66 × 10 ⁻²⁷ kilograms.
Slug
Slugs are used primarily in the British Imperial system in Great Britain and some other countries. One slug equal to mass a body that moves with an acceleration of one foot per second per second when a force of one pound-force is applied to it. This is approximately 14.59 kilograms.
Solar mass
Solar mass is a measure of mass used in astronomy to measure stars, planets and galaxies. One solar mass is equal to the mass of the Sun, that is, 2 × 10³⁰ kilograms. The mass of the Earth is approximately 333,000 times less.
Carat
Mass is measured in carats precious stones and metals in jewelry. One carat is equal to 200 milligrams. The name and the size itself are associated with the seeds of the carob tree (in English: carob, pronounced “carob”). One carat used to be equal to the weight of the seed of this tree, and buyers carried their seeds with them to check whether they were being deceived by sellers of precious metals and stones. The weight of a gold coin in Ancient Rome was equal to 24 carob seeds, and therefore carats began to be used to indicate the amount of gold in the alloy. 24 karat is pure gold, 12 karat is half gold alloy, and so on.
Grand
The grain was used as a measure of weight in many countries before the Renaissance. It was based on the weight of grains, mainly barley, and other popular crops at the time. One grain is equal to about 65 milligrams. This is a little more than a quarter of a carat. Until carats became widespread, grains were used in jewelry. This measure of weight is still used to this day to measure the mass of gunpowder, bullets, arrows, and gold foil in dentistry.
Other units of mass
In countries where the metric system is not adopted, the British Imperial system is used. For example, in the UK, USA and Canada, pounds, stones and ounces are widely used. One pound is equal to 453.6 grams. Stones are used mainly only to measure human body weight. One stone is approximately 6.35 kilograms or exactly 14 pounds. Ounces are primarily used in cooking recipes, especially for foods in small portions. One ounce is 1/16 of a pound, or approximately 28.35 grams. In Canada, which formally adopted the metric system in the 1970s, many products are sold in rounded imperial units, such as one pound or 14 fluid ounces, but are labeled with weight or volume in metric units. In English, such a system is called “soft metric” (English). soft metric), in contrast to the “rigid metric” system (eng. hard metric), in which the rounded weight in metric units is indicated on the package. This image shows "soft metric" food packaging with weight in metric units only and volume in both metric and imperial units.
Do you find it difficult to translate units of measurement from one language to another? Colleagues are ready to help you. Post a question in TCTerms and within a few minutes you will receive an answer.
ton; short tone listen)) is a non-metric unit of mass used in the United States. In the US it is often referred to simply as a "ton", while the metric and imperial (long) ton are specifically specified as to which one is used. However, there are some cases where the default is either the long ton (for example, when reporting the displacement of ships) or the metric ton (for example, data on world grain harvests).1 US ton = 20 short weight weights = 2000 merchant pounds = exactly 907.18474 kilograms.
Both long and short tons are defined as 20 handweights, but the definitions of handweights in English and American systems differ.
Unlike metric ton, which in English is written with two n(tonne), American ton is written with one n(ton).
See also
Write a review about the article "American ton"
An excerpt characterizing the American ton
– Quel soleil, hein, monsieur Kiril? (that’s what all the French called Pierre). On dirait le printemps. [What is the sun like, eh, Mr. Kiril? Just like spring.] - And the corporal leaned against the door and offered Pierre a pipe, despite the fact that he always offered it and Pierre always refused.“Si l"on marchait par un temps comme celui la... [It would be nice to go on a hike in such weather...],” he began.
Pierre asked him what had been heard about the march, and the corporal said that almost all the troops were marching out and that now there should be an order about the prisoners. In the booth in which Pierre was, one of the soldiers, Sokolov, was dying of illness, and Pierre told the corporal that he needed to dispose of this soldier. The corporal said that Pierre can be calm, that there is a mobile and permanent hospital for this, and that there will be orders for the sick, and that in general everything that can happen has been foreseen by the authorities.
- Et puis, monsieur Kiril, vous n "avez qu" a dire un mot au capitaine, vous savez. Oh, c"est un... qui n"oublie jamais rien. Dites au capitaine quand il fera sa tournee, il fera tout pour vous... [And then, Mr. Kiril, you should say a word to the captain, you know... He’s like that... he doesn’t forget anything. Tell the captain when he makes his rounds; he will do anything for you...]
In the US it is often referred to simply as a "ton", while the metric and imperial (long) ton are specifically specified as to which one is used. However, there are some cases where the default is either the long ton (for example, when reporting the displacement of ships) or the metric ton (for example, data on world grain harvests).
1 US ton = 20 short weight weights = 2000 merchant pounds = exactly 907.18474 kilograms.
Both long and short tons are defined as 20 handweights, but the definitions of handweights in English and American systems differ.
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See what “American ton” is in other dictionaries:
The request for "Ton" is redirected here; see also other meanings... Wikipedia
American ton (short ton) (eng. ton; short ton) is a non-metric unit of mass used in the United States. In the USA it is often called simply “ton”, while for the metric and English (long) ton it is specifically specified which ... Wikipedia
"Ton" redirects here. See also other meanings. Ton (French tonne, from the Middle Ages, Latin tunna barrel) is the name of some units of measurement of weight, mass and volume. Ton (metric ton) = 10 quintals = 1000 kilograms. Notation... Wikipedia
- (long ton) (eng. long ton, gross ton, weight ton) the name of the unit of measurement of mass, which in the English system of measures is called “ton”, used to distinguish it from other units with the same name (in other systems ... ... Wikipedia
English ton (long ton) (English long ton, gross ton, weight ton) the name of the unit of measurement of mass, which in the English system of measures is called "ton", used to distinguish it from other units with the same name (in others ... Wikipedia
Contents 1 Units of measurement of mass 1.1 The metric system 1.2 Measures of mass in science ... Wikipedia
- (cwt) (English hundredweight from hundred hundred and weight weight) a non-metric unit of mass in the USA and Great Britain. There are American and English handweights: American handweight (short handweight, short hundredweight, ... ... Wikipedia
Handweight (cwt) (English hundredweight from hundred hundred and weight weight) is a non-metric unit of mass in the USA and Great Britain. There are American and English handweights: American handweight (short handweight, short hundredweight, ... ... Wikipedia
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1 short ton = 907.184739999998 kilogram [kg]
Initial value
Converted value
kilogram gram exagram petagram teragram gigagram megagram hectogram decagram decigram centigram milligram microgram nanogram picogram femtogram attogram dalton, atomic mass unit kilogram-force square. sec./meter kilopound kilopound (kip) slug pound-force square. sec/foot pound troy pound ounce troy ounce metric ounce short ton long (English) ton assay ton (US) assay ton (Imperial) ton (metric) kiloton (metric) quintal (metric) quintal American quintal British quarter (US) quarter (British) stone (USA) stone (British) ton pennyweight scruple carat gran gamma talent (Dr. Israel) mina (Dr. Israel) shekel (Dr. Israel) bekan (Dr. Israel) gera (Dr. Israel) talent (Ancient Greece) mina (Ancient Greece) tetradrachm (Ancient Greece) didrachm (Ancient Greece) drachma (Ancient Greece) denarius (Ancient Rome) ass (Ancient Rome) codrant (Ancient Rome) lepton ( Dr. Rome) Planck mass atomic mass unit rest mass of an electron rest mass of a muon proton mass neutron mass deuteron mass mass of the Earth mass of the Sun Berkovets pud Pound lot spool share quintal livre
Kinematic viscosity
More about mass
General information
Mass is the property of physical bodies to resist acceleration. Mass, unlike weight, does not change depending on the environment and does not depend on the gravitational force of the planet on which this body is located. Mass m determined using Newton's second law, according to the formula: F = ma, Where F- this is strength, and a- acceleration.
Mass and weight
The word “weight” is often used in everyday life when people talk about mass. In physics, weight, in contrast to mass, is a force acting on a body due to the attraction between bodies and planets. Weight can also be calculated using Newton's second law: P= mg, Where m is the mass, and g- free fall acceleration. This acceleration occurs due to the gravitational force of the planet near which the body is located, and its magnitude also depends on this force. The acceleration of free fall on Earth is 9.80665 meters per second, and on the Moon it is approximately six times less - 1.63 meters per second. Thus, a body weighing one kilogram weighs 9.8 newtons on Earth and 1.63 newtons on the Moon.
Gravitational mass
Gravitational mass shows what gravitational force acts on a body (passive mass) and what gravitational force the body acts on other bodies (active mass). When increasing active gravitational mass body, its force of attraction also increases. It is this force that controls the movement and location of stars, planets and other astronomical objects in the universe. Tides are also caused by the gravitational forces of the Earth and Moon.
With increase passive gravitational mass the force with which the gravitational fields of other bodies act on this body also increases.
Inert mass
Inertial mass is the property of a body to resist movement. It is precisely because a body has mass that a certain force must be applied to move the body from its place or change the direction or speed of its movement. The greater the inertial mass, the greater the force required to achieve this. Mass in Newton's second law is precisely inertial mass. The gravitational and inertial masses are equal in magnitude.
Mass and relativity
According to the theory of relativity, gravitating mass changes the curvature of the space-time continuum. The greater the mass of a body, the stronger the curvature around this body, therefore, near bodies of large mass, such as stars, the trajectory of light rays is bent. This effect in astronomy is called gravitational lenses. On the contrary, far from large astronomical objects (massive stars or their clusters called galaxies), the movement of light rays is linear.
The main postulate of the theory of relativity is the postulate that the speed of propagation of light is finite. Several interesting consequences follow from this. Firstly, one can imagine the existence of objects with such a large mass that the second cosmic velocity of such a body will be equal to the speed of light, i.e. no information from this object will be able to reach the outside world. Such cosmic objects in the general theory of relativity are called “black holes” and their existence has been experimentally proven by scientists. Secondly, when an object moves at near-light speed, its inertial mass increases so much that local time inside the object slows down compared to time. measured by stationary clocks on Earth. This paradox is known as the “twin paradox”: one of them goes into space flight at near-light speed, the other remains on Earth. Upon returning from the flight twenty years later, it turns out that the twin astronaut is biologically younger than his brother!
Units
Kilogram
In the SI system, mass is expressed in kilograms. The kilogram is determined based on the exact numerical value of Planck's constant h, equal to 6.62607015×10⁻³⁴, expressed in J s, which is equal to kg m² s⁻¹, with the second and meter being determined by exact values c and Δ ν Cs. The mass of one liter of water can be approximately considered equal to one kilogram. The derivatives of kilogram, gram (1/1000 of a kilogram) and ton (1000 kilograms) are not SI units, but are widely used.
Electron-volt
Electronvolt is a unit for measuring energy. It is usually used in the theory of relativity, and energy is calculated using the formula E=mc², where E- this is energy, m- mass, and c- speed of light. According to the principle of equivalence of mass and energy, the electronvolt is also a unit of mass in the system of natural units, where c is equal to unity, which means mass equals energy. Electrovolts are mainly used in nuclear and atomic physics.
Atomic mass unit
Atomic mass unit ( A. e.m.) is intended for masses of molecules, atoms, and other particles. One a. e.m. is equal to 1/12 the mass of a carbon nuclide atom, ¹²C. This is approximately 1.66 × 10 ⁻²⁷ kilograms.
Slug
Slugs are used primarily in the British Imperial system in Great Britain and some other countries. One slug is equal to the mass of a body that moves with an acceleration of one foot per second per second when a force of one pound-force is applied to it. This is approximately 14.59 kilograms.
Solar mass
Solar mass is a measure of mass used in astronomy to measure stars, planets and galaxies. One solar mass is equal to the mass of the Sun, that is, 2 × 10³⁰ kilograms. The mass of the Earth is approximately 333,000 times less.
Carat
Carats measure the weight of precious stones and metals in jewelry. One carat is equal to 200 milligrams. The name and the size itself are associated with the seeds of the carob tree (in English: carob, pronounced “carob”). One carat used to be equal to the weight of the seed of this tree, and buyers carried their seeds with them to check whether they were being deceived by sellers of precious metals and stones. The weight of a gold coin in Ancient Rome was equal to 24 carob seeds, and therefore carats began to be used to indicate the amount of gold in the alloy. 24 karat is pure gold, 12 karat is half gold alloy, and so on.
Grand
The grain was used as a measure of weight in many countries before the Renaissance. It was based on the weight of grains, mainly barley, and other popular crops at the time. One grain is equal to about 65 milligrams. This is a little more than a quarter of a carat. Until carats became widespread, grains were used in jewelry. This measure of weight is still used to this day to measure the mass of gunpowder, bullets, arrows, and gold foil in dentistry.
Other units of mass
In countries where the metric system is not adopted, the British Imperial system is used. For example, in the UK, USA and Canada, pounds, stones and ounces are widely used. One pound is equal to 453.6 grams. Stones are used mainly only to measure human body weight. One stone is approximately 6.35 kilograms or exactly 14 pounds. Ounces are primarily used in cooking recipes, especially for foods in small portions. One ounce is 1/16 of a pound, or approximately 28.35 grams. In Canada, which formally adopted the metric system in the 1970s, many products are sold in rounded imperial units, such as one pound or 14 fluid ounces, but are labeled with weight or volume in metric units. In English, such a system is called “soft metric” (English). soft metric), in contrast to the “rigid metric” system (eng. hard metric), in which the rounded weight in metric units is indicated on the package. This image shows "soft metric" food packaging with weight in metric units only and volume in both metric and imperial units.
Do you find it difficult to translate units of measurement from one language to another? Colleagues are ready to help you. Post a question in TCTerms and within a few minutes you will receive an answer.
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