Question

Which of the following graphs correctly represents the relationship between the pressure and the volume of an ideal gas that is held at constant temperature?

Answer 1

Answer:

Option (d) represents the link between the pressure and therefore the volume of a perfect gas that's held at a continuing temperature. The graph of the link of temperature and one volume could be a graphical representation of Charles's law.

Explanation:

The graph shows the connection between volume vs temperature plotted at constant pressure for a hard and fast amount of gas. As are often observed from the graph, the degree increases with a rise within the temperature, and contrariwise. Thus, volume is directly proportional to temperature at a continuing pressure, which is that the statement of Gay-Lussac's law. Volume is plotted on the $y-$axis, and temperature is on $x-$axis. The graph could be a line with a positive slope passing the origin. The equation of the line is $V=kT,$ which is that the equation of Gay-Lussac's law. The slope of the road is k. As temperature approaches zero kelvin, volume also approaches zero. Real gases don't obey law of volumes at low temperatures. As temperature approaches temperature , the important gases start deviating significantly from Gay-Lussac's law.

#SPJ1

Answer 2

According to Boyle's Law:

Graph B represents the relationship between the pressure and the volume of an ideal gas that is held at constant temperature

Explanation:

Boyle's law is a gas law that describes the relationship between the pressure and volume of gas for a mass and temperature. This law is the mechanism by which the human respiratory system functions.

Boyle's law is important because it tells us about the behavior of gasses. It explains, with certainty, that the pressure and volume of gas are inversely proportional to one another. So, if you push on gas, its volume becomes smaller and the pressure becomes higher.

$P_1 V_1=P_2 V_2$

1. P1 is the initial pressure exerted by the gas
2. V1 is the initial volume occupied by the gas
3. P2 is the final pressure exerted by the gas
4. V2 is the final volume occupied by the gas

Hence,

option (B ) is correct.

Project code #SPJ1