The degree of dissociation of dimer and the equilibrium concentration ( K p ) at the particular temperature and pressure are to be calculated. Concept Introduction: An ideal gas can be characterized by three state variables, namely absolute pressure ( P ) , volume, and absolute temperature ( T ) . The relation between them that may be reduced from kinetic theory is called the ideal gas equation. The ideal gas equation is as follows: P V = n R T . Here, V is the volume, n is the number of moles, R is the universal gas constant, P is the pressure of the gas, and T is the temperature of the gas. The number of moles of a solute divided by the number of litres of solution is called molarity. The number moles of NaOH reacted with a dimer of acetic acid using the molarity is as follows: M o l a r i t y = M o l e s V o l u m e . The moles of the dimer are calculated as follows: Moles of dimer = M o l e s of NaOH 2 .
The degree of dissociation of dimer and the equilibrium concentration ( K p ) at the particular temperature and pressure are to be calculated. Concept Introduction: An ideal gas can be characterized by three state variables, namely absolute pressure ( P ) , volume, and absolute temperature ( T ) . The relation between them that may be reduced from kinetic theory is called the ideal gas equation. The ideal gas equation is as follows: P V = n R T . Here, V is the volume, n is the number of moles, R is the universal gas constant, P is the pressure of the gas, and T is the temperature of the gas. The number of moles of a solute divided by the number of litres of solution is called molarity. The number moles of NaOH reacted with a dimer of acetic acid using the molarity is as follows: M o l a r i t y = M o l e s V o l u m e . The moles of the dimer are calculated as follows: Moles of dimer = M o l e s of NaOH 2 .
Solution Summary: The author explains the degree of dissociation of dimer and the equilibrium concentration at the particular temperature and pressure are to be calculated.
The degree of dissociation of dimer and the equilibrium concentration (Kp) at the particular temperature and pressure are to be calculated.
Concept Introduction:
An ideal gas can be characterized by three state variables, namely absolute pressure (P), volume, and absolute temperature (T). The relation between them that may be reduced from kinetic theory is called the ideal gas equation.
The ideal gas equation is as follows:
PV=nRT.
Here, V is the volume, n is the number of moles, R is the universal gas constant, P is the pressure of the gas, and T is the temperature of the gas.
The number of moles of a solute divided by the number of litres of solution is called molarity.
The number moles of NaOH reacted with a dimer of acetic acid using the molarity is as follows:
Many moderately large organic molecules containing basicnitrogen atoms are not very soluble in water as neutral molecules,but they are frequently much more soluble as theiracid salts. Assuming that pH in the stomach is 2.5, indicatewhether each of the following compounds would be presentin the stomach as the neutral base or in the protonatedform: nicotine, Kb = 7 x 10-7; caffeine, Kb = 4 x10-14;strychnine, Kb = 1 x 10-6; quinine, Kb = 1.1 x 10-6.
The hydroxide ion concentration of an aqueous solution of 0.429 N acetylsalicylic acid (aspirin), HC9H7O4, is [OH-] = ________ M.
The pOH of an aqueous solution of 0.590 M phenol (a weak acid), C6H5OH, is _____
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