Is Matter Around Us Pure?

IS MATTER AROUND US PURE?

How do we judge whether milk, ghee, butter, salt, spices, mineral water or juice that we buy from the market are pure?

Fig. 2.1: Some consumable items

Have you ever noticed the word ‘pure’ written on the packs of these consumables? For a common person pure means having no adulteration. But, for a scientist all these things are actually mixtures of different substances and hence not pure. For example, milk is actually a mixture of water, fat, proteins, etc. When a scientist says that something is pure, it means that all the constituent particles of that substance are the same in their chemical nature. A pure substance consists of a single type of particle. In other words, a substance is a pure single form of matter.

As we look around, we can see that most of the matter around us exists as mixtures of two or more pure components, for example, sea water, minerals, soil, etc., are all mixtures.

2.1 What is a Mixture?

Mixtures are constituted by more than one kind of pure form of matter. We know that dissolved sodium chloride can be separated from water by the physical process of evaporation. However, sodium chloride is itself a pure substance and cannot be separated by physical process into its chemical constituents. Similarly, sugar is a substance which contains only one kind of pure matter and its composition is the same throughout.

Soft drink and soil are not single pure substances. Whatever the source of a pure substance may be, it will always have the same characteristic properties.

Therefore, we can say that a mixture contains more than one pure substance.

2.1.1 TYPES OF MIXTURES

Depending upon the nature of the components that form a mixture, we can have different types of mixtures.

Activity 2.1

Let us divide the class into groups A, $B, C$ and $D$.

  • Group A takes a beaker containing $50 mL$ of water and one spatula full of copper sulphate powder. Group B takes $50 mL$ of water and two spatula full of copper sulphate powder in a beaker.

  • Groups C and D can take different amounts of copper sulphate and potassium permanganate or common salt (sodium chloride) and mix the given components to form a mixture. Report the observations on the uniformity in colour and texture.

  • Groups A and B have obtained a mixture which has a uniform composition throughout. Such mixtures are called homogeneous mixtures or solutions. Some other examples of such mixtures are: (i) salt dissolved in water and (ii) sugar dissolved in water. Compare the colour of the solutions of the two groups. Though both the groups have obtained copper sulphate solution but the intensity of colour of the solutions is different. This shows that a homogeneous mixture can have a variable composition.

  • Groups C and D have obtained mixtures, which contain physically distinct parts and have non-uniform compositions. Such mixtures are called heterogeneous mixtures. Mixtures of sodium chloride and iron filings, salt and sulphur, and oil and water are examples of heterogeneous mixtures.

Activity 2.2

  • Let us again divide the class into four groups- A, B, C and D.

  • Distribute the following samples to each group:

    • Few crystals of copper sulphate to group A.

    • One spatula full of copper sulphate to group B.

    • Chalk powder or wheat flour to group $C$.

    • Few drops of milk or ink to group D.

  • Each group should add the given sample in water and stir properly using a glass rod. Are the particles in the mixture visible?

  • Direct a beam of light from a torch through the beaker containing the mixture and observe from the front. Was the path of the beam of light visible?

  • Leave the mixtures undisturbed for a few minutes (and set up the filtration apparatus in the meantime). Is the mixture stable or do the particles begin to settle after some time?

  • Filter the mixture. Is there any residue on the filter paper?

  • Discuss the results and form an opinion.

    Groups $A$ and $B$ have got a solution.

    Group $C$ has got a suspension.

    Group D has got a colloidal solution.

Fig. 2.2: Filtration

Now, we shall learn about solutions, suspensions and colloidal solutions in the following sections.

2.2 What is a Solution?

A solution is a homogeneous mixture of two or more substances. You come across various types of solutions in your daily life. Lemonade, soda water, etc., are all examples of solutions. Usually we think of a solution as a liquid that contains either a solid, liquid or a gas dissolved in it. But, we can also have solid solutions (alloys) and gaseous solutions (air). In a solution there is homogeneity at the particle level. For example, lemonade tastes the same throughout. This shows that particles of sugar or salt are evenly distributed in the solution.

Alloys: Alloys are mixtures of two or more metals or a metal and a non-metal and cannot be separated into their components by physical methods. But still, an alloy is considered as a mixture because it shows the properties of its constituents and can have variable composition. For example, brass is a mixture of approximately $30 %$ zinc and $70 %$ copper.

A solution has a solvent and a solute as its components. The component of the solution that dissolves the other component in it (usually the component present in larger amount) is called the solvent. The component of the solution that is dissolved in the solvent (usually present in lesser quantity) is called the solute.

Properties of a Solution

  • A solution is a homogeneous mixture.

  • The particles of a solution are smaller than $1 nm(10^{-9}.$ metre $)$ in diameter. So, they cannot be seen by naked eyes.

  • Because of very small particle size, they do not scatter a beam of light passing through the solution. So, the path of light is not visible in a solution.

  • The solute particles cannot be separated from the mixture by the process of filtration. The solute particles do not settle down when left undisturbed, that is, a solution is stable.

2.2.1 CONCENTRATION OF A SOLUTION

In activity 2.2, we observed that groups A and B obtained different shades of solutions. So, we understand that in a solution the relative proportion of the solute and solvent can be varied. Depending upon the amount of solute present in a solution, it can be called dilute, concentrated or saturated solution. Dilute and concentrated are comparative terms. In activity 2.2 , the solution obtained by group A is dilute as compared to that obtained by group B.

Activity 2.3

  • Take approximately $50 mL$ of water each in two separate beakers.

  • Add salt in one beaker and sugar or barium chloride in the second beaker with continuous stirring. When no more solute can be dissolved, heat the contents of the beaker to raise the temperature by about $5^{\circ} C$.

  • Start adding the solute again.

Is the amount of salt and sugar or barium chloride, that can be dissolved in water at a given temperature, the same?

At any particular temperature, a solution that has dissolved as much solute as it is capable of dissolving, is said to be a saturated solution. In other words, when no more solute can be dissolved in a solution at a given temperature, it is called a saturated solution. The amount of the solute present in the saturated solution at this temperature is called its solubility.

If the amount of solute contained in a solution is less than the saturation level, it is called an unsaturated solution.

What would happen if you were to take a saturated solution at a certain temperature and cool it slowly.

We can infer from the above activity that different substances in a given solvent have different solubilities at the same temperature.

The concentration of a solution is the amount (mass or volume) of solute present in a given amount (mass or volume) of solution.

There are various ways of expressing the concentration of a solution, but here we will learn only three methods.

(i) Mass by mass percentage of a solution

$ =\frac{\text{ Mass of solute }}{\text{ Mass of solution }} \times 100 $

(ii) Mass by volume percentage of a solution

$ =\frac{\text{ Mass of solute }}{\text{ Volume of solution }} \times 100 $

(iii) Volume by volume percentage of a solution

$ =\frac{\text{ Volume of solute }}{\text{ Volume of solution }} \times 100 $

2.2.2 WHAT IS A SUSPENSION?

Non-homogeneous systems, like those obtained by group $C$ in activity 2.2 , in which solids are dispersed in liquids, are called suspensions. A suspension is a heterogeneous mixture in which the solute particles do not dissolve but remain suspended throughout the bulk of the medium. Particles of a suspension are visible to the naked eye.

Properties of a Suspension

  • Suspension is a heterogeneous mixture.
  • The particles of a suspension can be seen by the naked eye.
  • The particles of a suspension scatter a beam of light passing through it and make its path visible.
  • The solute particles settle down when a suspension is left undisturbed, that is, a suspension is unstable. They can be separated from the mixture by the process of filtration. When the particles settle down, the suspension breaks and it does not scatter light any more.

2.2.3 WHAT IS A COLLOIDAL SOLUTION?

The mixture obtained by group D in activity 2.2 is called a colloid or a colloidal solution. The particles of a colloid are uniformly spread throughout the solution. Due to the relatively smaller size of particles, as compared to that of a suspension, the mixture appears to be homogeneous. But actually, a colloidal solution is a heterogeneous mixture, for example, milk.

Because of the small size of colloidal particles, we cannot see them with naked eyes. But, these particles can easily scatter a beam of visible light as observed in activity 2.2. This scattering of a beam of light is called the Tyndall effect after the name of the scientist who discovered this effect.

Tyndall effect can also be observed when a fine beam of light enters a room through a small hole. This happens due to the scattering of light by the particles of dust and smoke in the air.

Fig. 2.3: (a) Solution of copper sulphate does not show Tyndall effect, (b) mixture of water and milk shows Tyndall effect.

Tyndall effect can be observed when sunlight passes through the canopy of a dense forest. In the forest, mist contains tiny droplets of water, which act as particles of colloid dispersed in air.

Fig. 2.4: The Tyndall effect

Properties of a Colloid

  • A colloid is a heterogeneous mixture.

  • The size of particles of a colloid is too small to be individually seen with naked eyes.

  • Colloids are big enough to scatter a beam of light passing through it and make its path visible.

  • They do not settle down when left undisturbed, that is, a colloid is quite stable.

  • They cannot be separated from the mixture by the process of filtration. But, a special technique of separation known as centrifugation (perform activity 2.5), can be used to separate the colloidal particles.

The components of a colloidal solution are the dispersed phase and the dispersion medium. The solute-like component or the dispersed particles in a colloid form the dispersed phase, and the component in which the dispersed phase is suspended is known as the dispersing medium. Colloids are classified according to the state (solid, liquid or gas) of the dispersing medium and the dispersed phase. A few common examples are given in Table 2.1. From this table you can see that they are very common everyday life.

2.3 Physical and Chemical Changes

In the previous chapter, we have learnt about a few physical properties of matter. The properties that can be observed and specified like colour, hardness, rigidity, fluidity, density, melting point, boiling point etc. are the physical properites.

The interconversion of states is a physical change because these changes occur without a change in composition and no change in the chemical nature of the substance. Although ice, water and water vapour all look different and display different physical properties, they are chemically the same.

Both water and cooking oil are liquid but their chemical characteristics are different. They differ in odour and inflammability. We know that oil burns in air whereas water extinguishes fire. It is this chemical property of oil that makes it different from water. Burning is a chemical change. During this process one substance reacts with another to undergo a change in chemical composition. Chemical change brings change in the chemical properties of matter and we get new substances. A chemical change is also called a chemical reaction.

During burning of a candle, both physical and chemical changes take place. Can you distinguish these?

2.4 What are the Types of Pure Substances?

On the basis of their chemical composition, substances can be classified either as elements or compounds.

2.4.1 ELEMENTS

Robert Boyle was the first scientist to use the term element in 1661. Antoine Laurent Lavoisier (1743-94), a French chemist, was the first to establish an experimentally useful definition of an element. He defined an element as a basic form of matter that cannot be broken down into simpler substances by chemical reactions.

Elements can be normally divided into metals, non-metals and metalloids.

Metals usually show some or all of the following properties:

  • They have a lustre (shine).

  • They have silvery-grey or golden-yellow colour.

  • They conduct heat and electricity.

  • They are ductile (can be drawn into wires).

  • They are malleable (can be hammered into thin sheets).

  • They are sonorous (make a ringing sound when hit).

Examples of metals are gold, silver, copper, iron, sodium, potassium etc. Mercury is the only metal that is liquid at room temperature.

Non-metals usually show some or all of the following properties:

  • They display a variety of colours.

  • They are poor conductors of heat and electricity.

  • They are not lustrous, sonorous or malleable.

Examples of non-metals are hydrogen, oxygen, iodine, carbon (coal, coke), bromine, chlorine etc. Some elements have intermediate properties between those of metals and nonmetals, they are called metalloids; examples are boron, silicon, germanium, etc.

  • The number of elements known at present are more than 100. Ninety-two elements are naturally occurring and the rest are man-made.

  • Majority of the elements are solid.

  • Eleven elements are in gaseous state at room temperature.

  • Two elements are liquid at room temperature-mercury and bromine.

  • Elements, gallium and cesium become liquid at a temperature slightly above room temperature (303 K).

2.4.2 COMPOUNDS

A compound is a substance composed of two or more elements, chemically combined with one another in a fixed proportion.

What do we get when two or more elements are combined?

Activity 2.4

  • Divide the class into two groups. Give $5 g$ of iron filings and $3 g$ of sulphur powder in a china dish to both the groups.

    $ \mathrm{Group} \hspace{4px}\mathrm{I} $

  • Mix and crush iron filings and sulphur powder.

    $ \mathrm{Group} \hspace{4px}\mathrm{II} $

  • Mix and crush iron filings and sulphur powder. Heat this mixture strongly till red hot. Remove from flame and let the mixture cool.

    $ \mathrm{Group} \hspace{4px}\mathrm{I} $ $ \mathrm{and} \hspace{4px} \mathrm{Group} \hspace{4px}\mathrm{II} $

  • Check for magnetism in the material obtained. Bring a magnet near the material and check if the material is attracted towards the magnet. Compare the texture and colour of the material obtained by the groups.

  • Add carbon disulphide to one part of the material obtained. Stir well and filter.

  • Add dilute sulphuric acid or dilute hydrochloric acid to the other part of the material obtained.(Note: teacher supervision is necessary for this activity).

  • Perform all the above steps with both the elements (iron and sulphur) separately.

Now answer

  • Did the material obtained by the two groups look the same?

  • Which group has obtained a material with magnetic properties?

  • Can we separate the components of the material obtained?

  • On adding dilute sulphuric acid or dilute hydrochloric acid, did both the groups obtain a gas? Did the gas in both the cases smell the same or different?

The gas obtained by Group I is hydrogen, it is colourless, odourless and combustible-it is not advised to do the combustion test for hydrogen in the class. The gas obtained by Group II is hydrogen sulphide. It is a colourless gas with the smell of rotten eggs.

You must have observed that the products obtained by both the groups show different properties, though the starting materials were the same. Group I has carried out the activity involving a physical change whereas in case of Group II, a chemical change (a chemical reaction) has taken place.

  • The material obtained by group I is a mixture of the two substances. The substances given are the elements-iron and sulphur.
  • The properties of the mixture are the same as that of its constituents.

Table 2.2: Mixtures and Compounds

Mixture Compunds
1. Elements or compounds just mix together to form a mixture and no new compound is formed. 1. Elements react to form new compounds.
2. A mixture has a variable composition. 2. The composition of each new substance is always fixed.
3. A mixture shows the properties of the constituent substances. 3. The new substance has totally different properties.
4. The constituents can be seperated fairly easily by physical methods. 4. The constituents can be separated only by chemical or electrochemical reactions.
  • The material obtained by group II is a compound.
  • On heating the two elements strongly we get a compound, which has totally different properties compared to the combining elements.
  • The composition of a compound is the same throughout. We can also observe that the texture and the colour of the compound are the same throughout. Thus, we can summarise the physical and chemical nature of matter in the following graphical organiser:

What you have learnt

  • A mixture contains more than one substance (element and/ or compound) mixed in any proportion.
  • Mixtures can be separated into pure substances using appropriate separation techniques.
  • A solution is a homogeneous mixture of two or more substances. The major component of a solution is called the solvent, and the minor, the solute.
  • The concentration of a solution is the amount of solute present per unit volume or per unit mass of the solution.
  • Materials that are insoluble in a solvent and have particles that are visible to naked eyes, form a suspension. A suspension is a heterogeneous mixture.
  • Colloids are heterogeneous mixtures in which the particle size is too small to be seen with the naked eye, but is big enough to scatter light. Colloids are useful in industry and daily life. The particles are called the dispersed phase and the medium in which they are distributed is called the dispersion medium.
  • Pure substances can be elements or compounds. An element is a form of matter that cannot be broken down by chemical reactions into simpler substances. A compound is a substance composed of two or more different types of elements, chemically combined in a fixed proportion.
  • Properties of a compound are different from its constituent elements, whereas a mixture shows

Group Activity

Take an earthen pot (mutka), some pebbles and sand. Design a small-scale filtration plant that you could use to clean muddy water.



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