Mass is a measure of the amount of matter in an object, while area is a measure of the amount of space it occupies. The mass of an object is not directly related to its area, as mass depends on the volume of the object (which is related to both area and height for 3D objects). Different objects with the same area can have different masses depending on their density and shape.
The relation between density and pressure can be understood well with the help of the following derivation. Force = Mass x Acceleration →1 Pressure = Force / Area » Force = Pressure x Area →2 Equating 1 & 2 Pressure x Area = Mass x Acceleration Pressure = Mass x Acceleration / Area →3 Density = Mass / Volume » Mass = Density x Volume Eqn. 3 Becomes Pressure = Density x Volume x Acceleration / Area →4 i.e., Pressure is directly proportional to density.The relationship between density and temperature is the higher the temperature, the less the density.
The relation between velocity and area can vary depending on the specific situation. In general, when fluid flows through a pipe or channel, the velocity of the fluid is inversely proportional to the cross-sectional area of the pipe or channel. This means that as the area decreases, the velocity of the fluid tends to increase, and vice versa, according to the principle of conservation of mass.
The equation Emc2, proposed by Albert Einstein, shows the relationship between energy (E), mass (m), and the speed of light (c). It signifies that mass can be converted into energy and vice versa. In relation to momentum (pmc), the equation shows that momentum is directly proportional to mass and velocity, highlighting the connection between mass-energy equivalence and momentum in physics.
Mass and height are generally not directly related. Height is a measure of how tall someone is, while mass is a measure of the amount of matter in an object. While a person's height can affect their weight (mass), there is no strict correlation between height and mass for all individuals.
The mass flow rate and discharge pressure in a reciprocating compressor are directly related. As the discharge pressure increases, it can result in a higher mass flow rate through the compressor. This relationship is important for determining the performance and efficiency of the compressor in various operating conditions.
not particularly, essentially the effect of gravity depends on its mass and your distance from it
The period is independent of the mass.
It can't be done. You must also know at least any one of the following: Perimeter Relation between length and breath Relation between Area and length Relation between Area and breath Relation between perimeter and Area Breath and so on...........
mass number=atomic number+no. of neutrons
The mass of reactants is equal to the mass of products.
E=mc^2
Density = mass divided by volume, measured in kg per cubic metre
Pressure = force / area
There is no direct relation between the area of a sector and the length of an arc. You must know the radius (or diameter) or the angle of the sector at the centre.
In relation to the area of a circle: pi*radius^2
There is no relationship between units of mass and either length of capacity. Units of capacity are the cubed units of length.
The relation between density and pressure can be understood well with the help of the following derivation. Force = Mass x Acceleration →1 Pressure = Force / Area » Force = Pressure x Area →2 Equating 1 & 2 Pressure x Area = Mass x Acceleration Pressure = Mass x Acceleration / Area →3 Density = Mass / Volume » Mass = Density x Volume Eqn. 3 Becomes Pressure = Density x Volume x Acceleration / Area →4 i.e., Pressure is directly proportional to density.The relationship between density and temperature is the higher the temperature, the less the density.