In If n increases, V increases. If n decreases, V decreases. If V increases, n increases. If V decreases, n decreases. Avogadro’s Law states that if P and T...
1 Answers 1 views...according to the combined gas equation... We solve for....$V_2=(P_1V_1)/T_1xxT_2/P_2$ $=(150*kPaxx200*L)/(273*K)xx(546*K)/(600*kPa)=??*L$
1 Answers 1 viewsUse the : $P_1 V_1 = P_2 V_2$ . substituting and making the units consistent: $(200xx10^3)(2500)=(500xx10^3)(V_2)$. solve for $V_2$ .
1 Answers 1 viewsWe can use here the , relating the temperature, pressure, and volume of a gas with a constant quantity: $(P_1V_1)/(T_1) = (P_2V_2)/(T_2)$ If you're using the ideal-gas equation, which we're...
1 Answers 1 viewsAnd so.................. $V_2=(P_1xxV_1xxT_2)/(T_1xxP_2)$ $=(2.31*atmxx17.5*Lxx350*K)/(299*Kxx1.75*atm)<=30*L.$
1 Answers 1 viewsThis is an example of , which states that the volume of a gas varies inversely with pressure, as long as temperature and amount are kept constant. The equation to...
1 Answers 1 views$P*V=n*R*T " " $(Ideal gas law) Assuming that the amount of gas and the temperature are fixed, the product of the pressure and volume is constant at any given moment....
1 Answers 1 viewsWhen you are given this much information in the context of a generic, unnamed gas, it's a good idea to consider the : $PV = nRT$ Before we...
1 Answers 1 viewsThis is an example of the . The equation to use is $(P_1V_1)/(T_1)=(P_2V_2)/(T_2)$. Given Initial pressure, $P_1="250 kPa"$ Initial volume, $V_1="15 m"^3"$ Initial temperature, $T_1="100 K"$ Final pressure, $P_2="500 kPa"$...
1 Answers 1 viewsEven without doing any calculations, you should be able to look at the information given and predict that the volume of the gas will increase after temperature is increased and...
1 Answers 1 views