What is the physical state of substance which can be easily compressed on applying pressure?

What is the physical state of substance which can be easily compressed on applying pressure?

Gaseous state of the substance can be easily compressed on applying pressure.

Which state of the substance can be compressed easily?

gaseous state
Hence, the state of matter that can be easily compressed is the gaseous state.

Which one can be compressed by applying pressure?

Explanation: gas can be compressed by applying pressure because gas mimicked are very far so it can be compressed.

Which state of matter compressed easily and why?

The physical state of matter which can be easily compressed is the gaseous state . they are very easy to compress compared to solid and liquid because gas has more intermolecular space and very less force of attraction between the molecules.

Can be compressed into very small volumes by applying large pressure?

Gases have high compressibility. They can be compressed into very small volumes by applying large pressure. Due to its high compressibility, fairly large mass of gas can be put in a small metal cylinder by compression. Such gas cylinders can be easily transported from one place to another.

What are two characteristics of solid?

Solids are defined by the following characteristics:

• Definite shape (rigid)
• Definite volume.
• Particles vibrate around fixed axes.

Which of the following can be compressed easily?

Steam is easily compressible. Explanation: The atoms and molecules in gases are much more spread out in solid or liquid.

Which of the three states Cannot be compressed?

Remember liquids and solids cannot be compressed as their particles are already close together. The lighter the particles of gas, the faster the gas will diffuse.

Why the gas can be easily compressed by applying pressure?

Gases are compressible because most of the volume of a gas is composed of the large amounts of empty space between the gas particles. When a gas is compressed, as when the scuba tank is being filled, the gas particles are forced closer together. Compressed gases are used in many situations.

Which of the following can be easily compressed?

Which two states of matter are not easily compressed?

In solids, the particles are rigid and packed closely with each other. The intermolecular spaces between the molecules are negligible. Hence, solids cannot be compressed further.

Is pressure and volume direct or inverse?

For a fixed mass of an ideal gas kept at a fixed temperature, pressure and volume are inversely proportional. Or Boyle’s law is a gas law, stating that the pressure and volume of a gas have an inverse relationship. If volume increases, then pressure decreases and vice versa, when the temperature is held constant.

How do you find the compressibility of a gas?

Further explanation: The compressibility of gas can be seen in the ideal gas law PV = NRT; P – pressure V – volume N- moles R – constant T – Temp (in kelvin) If you hold the temperature and increase the pressure volume goes down. Q: Which state of matter can be easily compressed?

What happens to the sample when pressure is increased?

The sample is initially a gas, condenses to a solid as the pressure increases, and then melts when the pressure is increased further to give a liquid. In contrast to the phase diagram of water, the phase diagram of CO 2 (Figure 11.6.

What is the range of combinations of temperature and pressure?

Each region corresponds to the range of combinations of temperature and pressure over which that phase is stable. The combination of high pressure and low temperature (upper left of Figure 11.6. 1) corresponds to the solid phase, whereas the gas phase is favored at high temperature and low pressure (lower right).

Which combination of high pressure and low temperature corresponds to supercritical fluid?

The combination of high pressure and low temperature (upper left of Figure 11.6. 1) corresponds to the solid phase, whereas the gas phase is favored at high temperature and low pressure (lower right). The combination of high temperature and high pressure (upper right) corresponds to a supercritical fluid.