Read the text and answer the questions below.

Manufacturers determine which material to use for a given product by evaluating properties (qualities) of materials. Some properties can be linked with a material's macrostructure (structure visible to the unaided eye). Other properties are explained by a material's microstructure (structure that can be seen only through a microscope). The properties of materials are determined by their internal structure—that is, the way in which the fundamental parts of the materials are put together. At the most basic level, properties of materials are determined by chemical bonds, forces that attract atoms to one another and hold them together.

Materials scientists study how the structure of materials relates to their properties. A large part of their work involves experimentation.

Scientists group the properties of materials according to various functions that must be performed by objects made of the materials. Most properties of materials fall into six groups: (1) mechanical, (2) chemical, (3) electrical, (4) magnetic, (5) thermal, (6) optical.

Mechanical properties are critical in a wide variety of structures and objects—from bridges, houses, and space vehicles to chairs and even food trays. Some of; the most important mechanical properties are (1) stiffness, (2) yield stress, (3) toughness, (4) strength, (5) creep and (6) fatigue resistance.

Stiffness measures how much a material bends when first subjected to a mechanical force.

Yield stress measures how much force per unit area must be exerted on a material for that material to реrmanently deform (change its shape).

Toughness measures a material's resistance to cracking. The tougher a material, the greater the stress necessary to break that material near a crack.

Strength measures the greatest force a material can withstand without breaking. A material's strength depends on many factors, including its toughness and its shape.

Creep is a measure of a material's resistance to gradual deformation under a constant force.

Fatigue resistance measures the resistance of a material to repeated applications and withdrawals of force.

Chemical properties include catalytic properties and resistance to corrosion.

Electrical properties are important in products designed either to conduct (carry) or block the flow of electric current.

Dielectric strength describes a material's response to an electric field.

Magnetic properties indicate a material's response to a magnetic field—the region around a magnet or a conductor where the force of magnetism can be felt.

Thermal properties reflect a material's response to heat. Thermal conductivity is a measure of how well a material conducts heat.(2750 знаков)

 

1. What are the properties of materials linked with?

The properties of materials are linked with a material's macrostructure (structure visible to the unaided eye or with a material's microstructure (structure that can be seen only through a microscope).

2.What do materials scientists study?

Materials scientists study how the structure of materials relates to their properties.

3. How many groups of properties do the materials scientists distinguish and what are they?

Scientists distinguish the properties of materials according to various functions that must be performed by objects made of the materials. Most properties of materials fall into six groups: (1) mechanical, (2) chemical, (3) electrical, (4) magnetic, (5) thermal, (6) optical.

4. Does creep belong to mechanical properties of materials?

Yes, it does. Creep belongs to mechanical properties of materials.

5. Could you define major mechanical properties of materials?

The most important mechanical properties are (1) stiffness, (2) yield stress, (3) toughness, (4) strength, (5) creep and (6) fatigue resistance.

Stiffness measures how much a material bends when first subjected to a mechanical force.

Yield stress measures how much force per unit area must be exerted on a material for that material to реrmanently deform (change its shape).

Toughness measures a material's resistance to cracking. The tougher a material, the greater the stress necessary to break that material near a crack.

Strength measures the greatest force a material can withstand without breaking. A material's strength depends on many factors, including its toughness and its shape.

Creep is a measure of a material's resistance to gradual deformation under a constant force.

Fatigue resistance measures the resistance of a material to repeated applications and withdrawals of force.

6. What do chemical and electrical properties of materials include?

Chemical properties include catalytic properties and resistance to corrosion.

Electrical properties are important in products designed either to conduct (carry) or block the flow of electric current.

7. Why is it important to study magnetic and thermal properties of materials?

Studying of magnetic and thermal properties of materials is important because magnetic properties indicate a material's response to a magnetic field—the region around a magnet or a conductor where the force of magnetism can be felt. Another reason is that thermal properties reflect a material's response to heat.

 

 

TEXT C. Wood