The formula is:
T = PV/nR,
Where:
* T is the temperature in kelvin
* P is the pressure in atmospheres
* n is the number of moles
* R is the gas constant
Mercury is a good thermal conductor and has a wide range of temperature stability, making it suitable for use in thermometers. It expands and contracts evenly with temperature changes, allowing for accurate readings. It remains in liquid form across a wide temperature range, making it ideal for use in both high and low temperature environments.
The temperature of ice is 0 degrees Celsius. At this temperature, ice is in its solid form.
As air cools, it condenses into liquid form, making it difficult to accurately measure the temperature of the gas mixture. This can affect the determination of absolute zero because the liquid phase of air introduces additional complexities in measuring properties such as volume and pressure which are used to calculate temperature.
The ideal salt to water ratio for freezing water to make ice is about 1:10, meaning 1 part salt to 10 parts water. This ratio helps lower the freezing point of the water, allowing it to freeze at a lower temperature and form ice more effectively.
Boyle's law states that the pressure of an ideal gas is inversely proportional to its volume, when the temperature and amount of gas are kept constant. In equation form, it can be written as P1V1 = P2V2, where P1 and V1 represent the initial pressure and volume, and P2 and V2 represent the final pressure and volume of the gas.
The formula is: T = PV/nR, Where: * T is the temperature in kelvin * P is the pressure in atmospheres * n is the number of moles * R is the gas constant
To calculate the temperature of a gas using the ideal gas law, you would use the equation ( PV = nRT ). Rearranging this equation to solve for temperature ( T ), the formula becomes ( T = \frac{PV}{nR} ). Here, ( P ) is the pressure, ( V ) is the volume, ( n ) is the number of moles of gas, and ( R ) is the ideal gas constant. Make sure to use consistent units for pressure and volume to obtain temperature in Kelvin.
The formula is: T = PV/nR, Where: * T is the temperature in kelvin * P is the pressure in atmospheres * n is the number of moles * R is the gas constant
You would use the ideal gas law formula: PV = nRT, where P is pressure, V is volume, n is moles of gas, R is the gas constant, and T is temperature in Kelvin. Rearrange the formula to V = (nRT)/P to calculate volume.
Make V explicit in the general for of the gas law: P.V = n.R.T then you get V = (n.R.T) / P
From PV = nRT you solve for n (moles). Thus, n = PV/RT
(Explanation) this is simply taking the ideal gas law PV=nRT, and dividing by P on both sides to isolate the V, kinda like solving an algebra problem
From PV = nRT you solve for n (moles). Thus, n = PV/RT
From PV = nRT you solve for n (moles). Thus, n = PV/RT
From PV = nRT you solve for n (moles). Thus, n = PV/RT
From PV = nRT you solve for n (moles). Thus, n = PV/RT
From PV = nRT you solve for n (moles). Thus, n = PV/RT