Pressure exerted by 1 g of carbon dioxide in the flask of volume 1 L at 300 ° C has to be determined. Concept Introduction: An ideal gas contains a large number of randomly moving particles that are supposed to have perfectly elastic collisions among themselves. It is just a theoretical concept, and practically no such gas exists. At higher T and lower P gases behave almost ideally. Ideal gas law is an equation of state for any hypothetical gas. Expression for ideal gas equation is as follows: P V = n R T Here, P is the pressure of the gas. V is the volume of gas. n denotes the number of moles of gas. R is the gas constant. T is the temperature of gas.

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Chapter 3, Problem 3B.4AST

Interpretation Introduction

Interpretation:

Pressure exerted by 1 g of carbon dioxide in the flask of volume 1 L at 300 °C has to be determined.

Concept Introduction:

An ideal gas contains a large number of randomly moving particles that are supposed to have perfectly elastic collisions among themselves. It is just a theoretical concept, and practically no such gas exists. At higher T and lower P gases behave almost ideally.

Ideal gas law is an equation of state for any hypothetical gas. Expression for ideal gas equation is as follows:

PV=nRT

Here,

P is the pressure of the gas.

V is the volume of gas.

n denotes the number of moles of gas.

R is the gas constant.

T is the temperature of gas.

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