Use Boyle's Law: p*V=constant at same temperature
So let p2 be the wanted pressure in the 2nd flask (135 mL)
then: p2 * 135 = 67.5 * 326 , so p2 = 67.5 * 326/135 = 163 mmHg
(P at 1 atm)/(P at 2.5 atm)=(100+273)/Temperature at 2.5 atm932.5 k
Heat if transferred from the aluminum to the water, and the temperature of the water increase
The particles are far apart and moving randomly. Due to something called thermal equilibrium, an object, if left for a certain amount of time, will reach the same temperature as its surroundings. When a gas is placed in an environment that has, let's say, 1 atmosphere of pressure, it will equalize to 1 atmosphere of pressure, going from high pressure to low pressure. And the same will happen with temperature, so leave a gas in an environment for long enough and it will reach the same temperature and pressure as its environment.
An aerosol can contains compressed gas, which is already under pressure. If the gas is heated the pressure will increase, and if it heated a lot, the pressure will become great enough to cause an explosion. The connection between temperature and pressure comes about because temperature, on the molecular level, is determined by the speed at which the molecules are moving. And faster molecules have more energetic collisions, thereby exerting more pressure.
There are three main gas laws: Boyle's, Charles' and the pressure law. These describe the relationship between pressure, volume and temperature of an ideal gas. Boyle's law: the volume of a gas is inversely proportional to its pressure; i.e. doulbing the pressure applied to a gas will halve the volume it takes up (and vice-versa). Charles' law: the volume of a gas is directly proportional to its temperature; i.e. doulbing the temperature of a gas will double the volume it takes up (and vice-versa). Pressure law: the pressure of a gas is directly proportional to its temperature; i.e. doubling the temperature of a gas will double the pressure placed upon the gas (and vice-versa). These three laws can be combined with another to give the ideal gas law: PV = nRT (where P = pressure, V = volume, n = number of moles, R = universal gas constant and T = temperature in Kelvin). But seriously, next time, just Google it - it'll be faster. Or maybe read a textbook?
Gas molecules are spread out. When they are placed under pressure they condense into a liquid.
0.783 g of hydrogen gas is placed in an container of volume 657 mL at a temperature of 342 K. What is the pressure in atm?
Cute. Almost any gas can freeze if it's placed in an environment where the temperature is low enough and/or the pressure is high enough. But we can't think of a substance that's gaseous at the body's internal temperature and pressure and solidifies at any temperature and pressure that the same human could survive. Bottom line: We'd have to say 'no'.
(P at 1 atm)/(P at 2.5 atm)=(100+273)/Temperature at 2.5 atm932.5 k
No. Gravity exerts the same force on all objects regardless of how they are placed.
Heat if transferred from the aluminum to the water, and the temperature of the water increase
The particles are far apart and moving randomly. Due to something called thermal equilibrium, an object, if left for a certain amount of time, will reach the same temperature as its surroundings. When a gas is placed in an environment that has, let's say, 1 atmosphere of pressure, it will equalize to 1 atmosphere of pressure, going from high pressure to low pressure. And the same will happen with temperature, so leave a gas in an environment for long enough and it will reach the same temperature and pressure as its environment.
a tax placed on goods transferred within a country
When the dry ice is placed on the cooker it will explode, unless the temperature of the cooker is at a low degree.
A light layer of vacuum grease is applied to the rim of the belljar. Water at room temperature is placed inside and the vacuum pump is then used to evacuate the vessel. When the air pressure is reduced to the vapour pressure of water at room temperature the water will begin to boil.
the answer to thins question in inside your pants hahah but no its resistance
Generally, the air temperature of a descending air mass will increase. This is due to the incredible mount of pressure placed on it. Generally, the air mass will also experience an increase in humidity.