Higher pressures
this gives more collisions which is a goal of the gases
Gases behave most ideally at low pressure and high temperatures. At low pressures, the average distance of separation among atoms or molecules is greatest, minimizing interactive forces. At high temperatures, the atoms and molecules are in rapid motion and are able to overcome interactive forces more easily.
No - the ideal gas law is an approximation for ideal gases, it doesn't apply exactly for real gases. Deviations are greater at very small temperatures, or very high pressures.
It is assumed that Ideal Gases have negligible intermolecular forces and that the molecules' actualphysical volume is negligible. Real Gases have the molecules closer together so that intermolecular forces and molecules' physical volumes are no longer negligible. High pressures and low temperatures tend to produce deviation from Ideal Gas Law and Ideal Gas behavior.
is it true the space between gas particles becomes very large
Fartting is not ideal
The partial pressure is the pressure exerted by just one gas in the mixture.
The total pressure of a mixture of gases is the sum of partial pressures of contained gases.
Ideal gases can be condensed, but the ideal gas model may fail for gases at higher temperatures.
An ideal gas is, precisely, an idealization - a ficticious substance that will NOT liquify, but remain a gas, and have a volume that is exactly proportional to the temperature (at a given pressure). Real gases are an approximation to an ideal gas, under a wide variety of conditions, but at low temperatures, or high pressures, there are discrepancies.
There are ideal gases..
Assuming that you mean "Dalton's Law"... In chemistry and physics, Dalton's law (also called Dalton's law of partial pressures) states that the total pressure exerted by the mixture of non-reactive gases is equal to the sum of the partial pressures of individual gases. This empirical law was observed by John Dalton in 1801 and is related to the ideal gas laws.
Ideal gases will not liquify at low temperatures because they have no intermolecular forces.