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K. "Mass" and "Weight" [See Section K. NOTE] The mass of an object is a measure of the object’s inertial property, or the amount of matter it contains. The weight of an object is a measure of the force exerted on the object by gravity, or the force needed to support it.
The magnitude of force that the table is pushing upward on the object (the N vector) is equal to the downward force of the object's weight (shown here as mg, as weight is equal to the object's mass multiplied with the acceleration due to gravity): because these forces are equal, the object is in a state of equilibrium (all the forces and ...
Specific energy has the same units as specific strength, which is related to the maximum specific energy of rotation an object can have without flying apart due to centrifugal force. The concept of specific energy is related to but distinct from the notion of molar energy in chemistry , that is energy per mole of a substance, which uses units ...
The kilogram (also spelled kilogramme [1]) is the base unit of mass in the International System of Units (SI), having the unit symbol kg. [1] The word "kilogram" is formed from the combination of the metric prefix kilo-(meaning one thousand) and gram; [2] it is colloquially shortened to "kilo" (plural "kilos").
moment of force: m 2 ⋅kg⋅s −2: newton per metre N/m surface tension: kg⋅s −2: radian per second: rad/s angular velocity, angular frequency: s −1: radian per second squared: rad/s 2: angular acceleration: s −2: watt per square metre: W/m 2: heat flux density, irradiance: kg⋅s −3: joule per kelvin: J/K entropy, heat capacity: m ...
Thermodynamic work is one of the principal kinds of process by which a thermodynamic system can interact with and transfer energy to its surroundings. This results in externally measurable macroscopic forces on the system's surroundings, which can cause mechanical work, to lift a weight, for example, [1] or cause changes in electromagnetic, [2] [3] [4] or gravitational [5] variables.
If a first body of mass m A is placed at a distance r (center of mass to center of mass) from a second body of mass m B, each body is subject to an attractive force F g = Gm A m B /r 2, where G = 6.67 × 10 −11 N⋅kg −2 ⋅m 2 is the "universal gravitational constant". This is sometimes referred to as gravitational mass.
The heat capacitance may be written in terms of the object's specific heat capacity, (J/kg-K), and mass, (kg). The time constant is then τ = m c / ( h A ) {\displaystyle \tau =mc/(hA)} . When the environmental temperature is constant in time, we may define Δ T ( t ) = T ( t ) − T env {\displaystyle \Delta T(t)=T(t)-T_{\text{env}}} .