State which of the three states of matter i.e. solids, liquids or gases - have
a] No definite volume b] A definite shape c] High density e] No free surfaces f] Particles - which diffuse very easily.

In which of the three states of matter - solids, liquids or gases is the movement of atoms about their own position. Give a reason for the same.

Explain the following on the basis of kinetic theory of matter. a.Solids have a definite volume and definite shape. b. Liquids have a definite volume, but no definite shape. c. Gases have a no definite volume and no definite shape.

Which of the following statements is not correct about the three states of matter, i.e., solid, liquids and gas?

The state of matter which has no definite shape or volume is called

Out of three states of matter, only the gases have most of the physical properties common. They have neither definite shapes nor definite volume. In addition to this, the gases obey different gas laws such as Boyles's law. Charles law, Dalton's law of partial pressures etc. Based upon these gas laws, ideal gas equation PV = nRT has been derived. Answer the following questions on the basis of above paragraph. (i) what is Dalton's law of partial pressures ? (ii) Derive ideal gas equation on the basis of all gas laws.

Out of the three states of matter, only the gases have most of the physical properties common. They neither have definite shapes nor volumes. Upon mixing they form homogeneous mixture irrespective of their nature and can also be compressed on applying pressure. In addition to these, the gases obey different gas laws such as Boyle's Law, Charles's Law, Dalton's Law of partial pressures, Graham's Law of diffusion etc. Based upon these laws, ideal gas equation PV = nRT has been derived. Which pair of gaseous species diffuse through a small jet with the same rate of diffusion at same P and T ?

Out of the three states of matter, only the gases have most of the physical properties common. They neither have definite shapes nor volumes. Upon mixing they form homogeneous mixture irrespective of their nature and can also be compressed on applying pressure. In addition to these, the gases obey different gas laws such as boyle's Law, Charles's Law, Dalton's Law of partial pressures, Graham's Law of diffusion etc. Based upon these laws, ideal gas equation PV = nRT has been derived. 4-4 g of a gas at STP occupies a volume of 2.224 L. The gas can be :

Out of the three states of matter, only the gases have most of the physical properties common. They neither have definite shapes nor volumes. Upon mixing they form homogeneous mixture irrespective of their nature and can also be compressed on applying pressure. In addition to these, the gases obey different gas laws such as boyle's Law, Charles's Law, Dalton's Law of partial pressures, Graham's Law of diffusion etc. Based upon these laws, ideal gas equation PV = nRT has been derived. When the product of pressure and volume is plotted against pressure for a given amount of a gas, the obtained is

Out of the three states of matter, only the gases have most of the physical properties common. They neither have definite shapes nor volumes. Upon mixing they form homogeneous mixture irrespective of their nature and can also be compressed on applying pressure. In addition to these, the gases obey different gas laws such as Boyle's Law, Charles's Law, Dalton's Law of partial pressures, Graham's Law of diffusion etc. Based upon these laws, ideal gas equation PV = nRT has been derived. For an ideal gas, number of moles per litre in terms of its pressure P, gas constant R and temperature T is :

Out of the three states of matter, only the gases have most of the physical properties common. They neither have definite shapes nor volumes. Upon mixing they form homogeneous mixture irrespective of their nature and can also be compressed on applying pressure. In addition to these, the gases obey different gas laws such as Boyle's Law, Charles's Law, Dalton's Law of partial pressures, Graham's Law of diffusion etc. Based upon these laws, ideal gas equation PV = nRT has been derived. Same mass of CH_(4) and H_(2) at taken in a container. The partial pressure caused by H_(2) is