Answer

(c) Homogeneous catalysis does not occur at the interface of phases as in case of homogeneous catalysis reactant and catalyst have same phase and their distribution is uniform throughout.

Answer

(b) As we know that, at equilibrium $\Delta G=0$

$$ \begin{aligned} \Delta H-T \Delta S & =0 \\ \Delta H & =T \Delta S \end{aligned} $$

Hence, at equilibrium enthalpy change is equal to product of temperature and entropy change.

Answer

(d) Gas-gas interface can not be obtained as they are completely miscible in nature.

e.g., air is a mixture of various gases such as, $O_2, N_2, CO_2$ etc.

Answer

(c) Sorption stands for both absorption and adsorption. We can understand this by using following figures

Answer

(b) Extent of physisorption of a gas increases with decrease in temperature. Because in physisorption particles are held to the surface by weak van der Waals’ force of attraction hence on increasing temperature they get desorbed easily.

Answer

(a) Extent of adsorption of adsorbate from solution phase increases with increase in amount of adsorbate in solution. As amount of adsorbate in the solution increases interaction of adsorbate with adsorbent increases which lead to increase in extent of adsorption.

Answer

(a) For phenomenon of adsorption $\Delta H<0$, i.e., enthalpy change during phenomenon of adsorption is negative because during adsorption, there is always a decrease in residual forces of the surface which lead to decrease in surface energy which appears as heat.

So, adsorption is an exothermic process and $\Delta H<0$.

Answer

(d) Physisorption is a process in which adsorbate get adsorbed on the adsorbent surface by weak van der Waals’ force of attraction. On increasing temperature the interaction between adsorbate and adsorbent becomes weak and adsorbate particles get desorbed.

Answer

(b) On increasing temperature physisorption changes to chemisorption. As temperature increases, energy of activation of adsorbate particles increases which lead to formation of chemical bond between adsorbate and adsorbent.

Hence, physisorption transform into chemisorption.

Answer

(a) In physisorption adsorbent does not show specificity for any particular gas because involved van der Waals’ forces are universal. It means extent of van der Waals’ interaction between adsorbate and adsorbent is constant for all gases.

Answer

(b) Absorption means penetration of adsorbate molecules into the bulk of the adsorbent e.g., water on calcium chloride. When water is spread over calcium chloride, water get penetrate into bulk of the calcium chloride.

Thinking Process

This problem includes concept of extent of conjugation and critical temperature. Extent of adsorption is directly related to critical temperature of gases.

Answer

(d) Lesser the value of critical temperature of gases lesser will be the extent of adsorption. Here $H_2$ has lowest value of critical temperature, i.e., 33.

Hence, hydrogen gas shows least adsorption on a definite amount of charcoal.

Answer

(c) (i) Reaction in which catalyst is in different phase than other (reactants and products) is known as heterogeneous catalysis.

(ii) $2 SO_2(g) \xrightarrow{Pt(s)} 2 SO_3(g)$

Here, reactant $SO_2$ and product $SO_3$ are in gaseous phase while platinum is in solid phase. So, this reaction represents a heterogeneous catalysis.

(iii) $N_2(g)+3 H_2(g) \xrightarrow{Fe(s)} 2 NH_3(g)$

Similarly, here $N_2$ and $H_2$ reactants are in gaseous phase while $NH_3$ is in solid phase. Whereas in other reactions catalyst is in same phase with reactant(s) and product(s).

Answer

(b) Associated colloid At high concentration of soap in water, soap particles present in the solution get associated around and lead to formation of associated colloid.

Answer

(b) Aqueous solution of soap above critical micelle concentration lead to formation of colloidal solution. Tyndall effect is a characteristic of colloidal solution in which colloidal particles show a coloured appearance when sunlight is passes through it and seen from the perpendicular side.

Answer

(c) Lyophobic sol can be protected by addition of lyophilic sol. As lyophobic sols are readily precipitated on addition of small amount of electrolytes or shaking, or heating hence they are made stable by adding lyophillic sol which stabilises the lyophobic sols.

Answer

(d) Freshly prepared precipitate sometimes gets converted to colloidal solution by peptisation. Peptisation is a process in which by addition of a suitable peptising agent precipitate gets converted into colloidal solution.

Thinking Process

This problem includes concept of Hardy-Schulze law. According to which higher charge on oppositely charge ion of electrolyte decide the coagulating power of colloid.

Answer

(b) According to Hardy-Schulze law, greater the charge on anion greater will be its coagulating power.

Here, $PO_4^{3-}$ have highest charge. Hence, $PO_4^{3-}$ have highest coagulating power.

Answer

(d) Sol is a colloidal system in which solid substance is a dispersed phase and a liquid is a dispersion medium. e.g., paint, cell fluids etc.

In paints solid colouring particles are dissolved in liquid dispersion medium.

Answer

(d) The value of colligative properties of colloidal solution are of small order in comparison to those of true solution of same concentration because of colloidal particles are comparatively less in number.

This is due to slight large size of colloidal particles in comparison to particles present in true solution. Size of colloidal particles is in between $1 nm$ to $1000 nm$.

Answer

(b) Correct sequence is $I \rightarrow III \rightarrow Ii \rightarrow I V \rightarrow V$

Each transformation denotes a meaningful process as follows

I $\rightarrow$ adsorption of $A$ and $B$ on surface

III $\rightarrow$ II interaction between $A$ and $B$ to form intermediate

Answer

(c) River water is a colloidal solution of clay and sea. Water contains various electrolytes. When river water comes in contact with sea water, then the electrolytes present in sea water coagulate the suspended colloidal particles which ultimately settle down at the point of contact.

Answer

(c) According to the Freundlich adsorption isotherm

$$ \frac{x}{m}=k p^{\frac{1}{n}} $$

Taking log on both side $\underset{\substack{\uparrow \\ \\ \mathrm{Y}}}{\log \frac{x}{m}}=\underset{\substack{\uparrow \\ \\ \mathrm{= m}}}{(\frac{1}{n})} \underset{\substack{\uparrow \\ \\ x}}{\log p}+\underset{\substack{\uparrow \\ \\ \mathrm{+ C}}}{\log k}$

On comparing it with equation of straight line and drawing the graph $\log \frac{x}{m}$ versus $\log p$, we get a straight line with intercept $\log k$ and slope of the straight line gives the value of $\frac{1}{n}$.

Answer

(d) Absorption of ionic species from solution is not responsible for the presence of electric charge on the sol particles. Charge on the sol particles is due to

(i) electrons capture by sol particles during electro dispersion of metal.

(ii) preferential adsorption of ionic species from solution.

(iii) formation of Helmholtz electrical double layer.

Answer

(b) Above figure represent adsorption of yellowish brown colour of raw sugar by animal charcoal.

Here, aqueous solution of raw sugar is filtered by using animal charcoal. Yellowish brown colour of raw sugar is adsorbed and filterate is colourless which gives white colour on cystallisation. Hence, this phenomenon is adsorption.

Thinking Process

This problem is based on concept of micelle formation and CMC (critical micelle concentration).

Answer

$(b, c)$

Micelle formation Some substances at low concentration behaves as a normal electrolytes but at higher concentration exhibit colloidal behaviour due to formation of micelles.

CMC (Critical Micelle Concentration) The concentration above which it behaves as a micelle known as critical micelle concentration (CMC).

e.g., soap solution in aqueous solution above particular concentration (called CMC $=10^{-4}-10^{3} mol L^{-1}$ ) forms soap micelles.

On dilution soap solution behaves as a normal electrolyte and after adding excess of water intermolecular force of attraction between the soap particles decreases and soap solution micelles may revert to individual ions.

Answer

$(a, b)$

(a) Same reactants may give different products by using different catalysts as different catalysts have different specific functions to mold the reaction towards specific product.

e.g., starting with $H_2$ and $CO$, and using different catalysts, we get different products.

(i) $CO(g)+3 H_2 \xrightarrow{Ni} CH_4(g)+H_2 O(g)$

(ii) $CO(g)+2 H_2(g) \xrightarrow[Cr_2 O_3]{\stackrel{Cu / ZnO}{\longrightarrow}} CH_3 OH(g)$

(iii) $CO(g)+H_2(g) \xrightarrow{Cu} HCHO(g)$

(b) Catalyst does not change $\Delta H$ of reaction as $\Delta H$ of reaction is difference between enthalpy of reactants and products. So, it does not change during catalysed reaction.

Thinking Process

To solve this problem follow steps given below.

Write Freundlich equation and transform it into different form depending upon value of $n$ then choose the correct answer.

Answer

$(a, c)$

According to Freundlich adsorption isotherm

$$ \frac{x}{m} \propto p^{\frac{1}{n}} \Rightarrow \frac{x}{m}=k p^{\frac{1}{n}} $$

(a) At $\frac{1}{n}=0$ this equation becomes $\frac{x}{m}=k p^{0}=k$

Extent of adsorption is independent of pressure.

(c) At $x=0, \quad \frac{x}{m}=k p^{\frac{1}{0}}=k p^{\infty}$

Hence, $\frac{x}{m}$ vs $p$ graph can be plotted as

Answer

$(b, c)$

$H_2$ gas is adsorbed on activated charcoal to a very little extent in comparison to easily liquefiable gases due to

(i) very low van der Waals’ forces and

(ii) very low critical temperature equal to $33 K$.

Answer

$(b, d)$

Presence of equal and similar charges on colloidal particles provides stability to colloids as repulsive forces between charge particles having same charge prevent them from colliding when they come closer to each other.

Answer

$(b, d)$

Emulsions are liquid-liquid colloidal system. They can’t be broken by adding more amount of dispersion medium and adding emulsifying agent as on adding more amount of dispersion medium they become dilute and on adding emulsifying agent they get stabilises.

Answer

$(a, d)$

The droplets present in emulsion has negative charge. It can be precipitated by adding electrolyte such as $KCl, NaCl$ etc. Since, glucose and urea do not produce ions on dissolving in water.

Hence, they are non-electrolyte and do not precipitate the negatively charged emulsion.

Answer

(c, $d$)

Lyophilic colloids (liquid loving colloids) which are also known as reversible colloid can’t be coagulated easily. The stability of these colloids are due to (i) charge on colloidal particles and (ii) solvation of colloidal particles.

Answer

$(a, c)$

Lyophobic sol is unstable in nature when lyophilic sol is added to lyophobic sol then lyophobic sol is protected because a film of lyophilic sol is formed over lyophobic sol.

Hence, (a) and (c) are correct.

Thinking Process

This problem is based on concept of electroosmosis. It can be solved by knowing the exact meaning of electroosmosis

Answer

$(b, c)$

The movement of colloidal particles under an applied electric potential is called electrophoresis. When this movement of particles is prevented by some suitable means, it is observed that the dispersion medium begins to move in an electric field. This phenomenon is termed as electroosmosis.

Answer

$(a, b)$

In a reaction catalyst changes physically and qualitatively as it is unaltered during the reaction and remain quantitatively intact after completion of reaction and chemically does not change.

Answer

$(a, d)$

When a chalk stick is dipped in ink absorption as well as absorption both occurs. Adsorption of coloured substance and absorption of solvent takes place.

Answer

It facilitates the adsorption of desired species. If surface is covered by the gases of air then it will not be available for adsorption of desired gases. So, it is very important to have clean surface in surface studies i.e., study of surface chemistry.

Answer

Chemisorption referred to as activated adsorption as it involves chemical bond formation between reactant and adsorbent molecules. Formation of chemical bond requires high activation energy. So, it is activated on increasing temperature.

Answer

At lower concentration, soap behaves as a normal solution of electrolyte in water. However, after a certain concentration, called critical micelle concentration, colloidal solution is formed due to aggregation of colloidal particles.

$CMC$ for soap solution is $10^{-4}$ to $10^{-3} mol L^{-1}$.

Answer

Gold sol is a solvent repelling sol i.e., a lyophobic sol and unstable in nature. Addition of gelatin stabilises the gold sol because gelatin forms lyophilic sol and act as a protective colloid.

Answer

As we know artificial rainfall occurs when oppositely charged clouds meets. Since, clouds are colloidal in nature and carry charge. Spray of silver iodide, an electrolyte from aeroplane results in coagulation of colloidal water particles leading to rain. Sometimes electrified sand is also used for this purpose.

Answer

Emulsifying agent is added to emulsion to stabilise the emulsion. Emulsifying agent form a layer between suspended particles and the medium and hence stabilises the emulsion. Ice cream (emulsion) is stabilised by emulsifying agent like gelatin.

Answer

$4 $% solution of nitrocellulose in a mixture of alcohol and ether is called collodion.

Answer

We add alum to purify water as alum coagulates the colloidal impurities present in water, so that these impurities get settle down and remove by decantation or filtration. Thus, water gets purified by adding alum to water.

Answer

When electric potential is applied to colloidal solution, the colloidal particles move towards one or other electrode. Positively charged particles move towards the cathode while negatively charged particles move towards the anode.

The movement of colloidal particles under an applied electric potential is called electrophoresis. When electrophoresis is prevented by some means, then the dispersion medium begins to move in an electric field. This phenomenon is termed as electroosmosis.

Answer

Brownian movement may be defined as continuous zig-zag movement of colloidal particles in a colloidal sol. A state of continuous zig-zag motion of colloidal particles appears to be in view due to unbalanced bombardment of the particles of dispersed phase by molecules of dispersion medium. This Brownian movement stabilises the sol.

Answer

Positively charged ions coagulate the negatively charged sol and negatively charged ion coagulate the positively charged sol. Positively charged sol of hydrated ferric oxide is formed when $FeCl_3$ is added in excess of hot water. On adding excess of $NaCl$ to this sol, negatively charged $Cl^{-}$ions coagulate the positively charged sol of hydrated ferric oxide.

Answer

Emulsifying agents stabilise the emulsion by forming an interfacial layer between suspended particles and the dispersion medium. e.g., gelatin is added to ice cream to stabilise it.

Answer

Some medicines are more effective in colloidal form because they have large surface area so easily assimilated in the body.

Answer

Animal hide is colloidal in nature and has positively charged particles. When it is soaked in tanin (negatively charged), a colloid, it results in mutual coagulation and gets harden. Thus, leather get hardened after tanning.

Answer

In Cottrell precipitator, smoke particles (charged) are passed through a chamber containing plates with charge opposite to the smoke particles, smoke particles lose their charge on the plates and get precipitated.

Answer

To distinguish between dispersed phase and dispersion medium we increase the concentration of any one dispersion medium or dispersed phase then notice the change.

When dispersion medium is added to an emulsion, it gets diluted to any extent. But on adding dispersed phase it forms a separate layer, if added in excess.

Answer

Minimum quantity of an electrolyte required to cause precipitation of a sol is called its coagulating value. Greater the charge on flocculating ion and smaller is the amount of electrolyte required for precipitation, higher is the coagulating power of coagulating ion (Hardy-Schulze Law).

Phosphate ion bear -3 charge while chloride ion carries only -1 charge and due to high charge phosphate ion has high coagulating power than that of chloride ion.

Answer

Blood is a colloidal sol. When we rub the injured part with moist alum then coagulation of blood takes place. Hence, main reason is coagulation, which stops the bleeding.

Answer

Charge on sol is decided by adsorption of ions present in medium. Adsorption of positively charged $Fe^{3+}$ ions takes place by the sol of hydrated ferric oxide. Thus, $Fe(OH)_3$ colloid has positive charge when prepared by adding $Fe(OH)_3$ to hot water.

Answer

Behaviour of physisorption and chemisorption on increase in temperature can be explained on the basis of nature of forces present to bind their particles. Physisorption involves weak van der Waals’ forces which weakens with increase in temperature.

Chemisorption involves formation of chemical bond which requires activation energy hence, it is favoured by rise in temperature.

Answer

Traces of electrolyte which stabilises the colloids is removed completely making the colloid unstable. So, coagulation occurs on prolonged dialysis.

Answer

White coloured precipitate of silver halide becomes coloured in the presence of dye eosin because dye eosin (coloured) gets adsorbed on the surface of silver halide precipitate.

Answer

Role of activated charcoal in gas mask can be explained on the basis of adsorption. Activated charcoal adsorbs various poisonous gases on its surface present in coal mines.

Answer

Formation of delta at the meeting place of sea and river water is due to coagulation. River water (colloid of sea water + clay) has many dissolved electrolytes. The place where river meets sea is the site for coagulation. Deposition of coagulated clay results in delta formation.

Answer

Adsorption of $H_2$ on finely divided nickel (physisorption) involves weak van der Waals’ forces. When temperature is increased, hydrogen molecules dissociate into hydrogen atoms, form chemical bonds with the metal atoms at the surface (chemisorption).

Answer

Desorption is important for a substance to act as a good catalyst so that after the reaction, the products formed on the surface separate out (desorbed) to create free surface again for other reactant molecules to approach the surface and react.

If desorption does not occur then other reactants are left with no space on the catalysts surface for adsorption and reaction will stop.

Answer

Diffusion of gas molecules occur at the surface of catalyst (solid) followed by adsorption. In the same way, the product formed diffuse from the surface of the catalyst leaving the surface free for more reactant molecules to get adsorbed and undergo reaction.

Answer

When gaseous molecules come in contact with the surface of a solid catalyst, a weak chemical bond is formed between the surface (catalyst) molecules and reactant (gas) molecules. Thus, concentration of reactant molecules increases at the surface.

The rate of reaction increases by adsorption of different molecules side by side facilitating the chemical reaction. Adsorption, being exothermic also help in increasing the rate of reaction (chemisorption increases with rise in temperature).

Answer

The optimum temperature range for enzymatic activity is $298-310 K$, i.e., enzymes are inactive beyond this temperature range (high or low).

Thus, during fever (temperature $>310 K$ ) the activity of enzymes may be affected.

Answer

A. $\rightarrow(2)$

B. $\rightarrow(3)$

C. $\rightarrow(4)$

D. $\rightarrow(1)$

A. When sulphur vapours passed through cold water it leads to formation of molecular colloids.

B. When soap is mixed with water above critical micelle concentration it lead to formation of associated colloids.

C. White of egg whipped with water is an example of macromolecular colloids in which high molecular mass proteneous molecule acts as a colloidal particle.

D. Soap mixed with water below critical micelle concentration is known as normal electrolyte solution.

Answer

A. $\rightarrow(3)$

B. $\rightarrow(4)$

C. $\rightarrow(2)$

D. $\rightarrow(1)$

A. Dispersion medium moves in an electric field is known as electroosmosis.

B. Solvent molecules pass through semipermeable membrane towards solvent side is known as reverse-osmosis.

C.Movement of charged colloidal particles under the influence of applied electric potential towards oppositely charge electrodes is known as electrophoresis.

D. Solvent molecules pass through semipermeable membranes towards solution side is known as osmosis.

Answer

A. $\rightarrow(2)$

B. $\rightarrow$ (3)

C. $\rightarrow(4)$

D. $\rightarrow(1)$

A. Lyophobic colloid (solvent hating colloid) are readily protected by small amount of electrolyte. These colloids are also stabilised by addition of lyophilic colloids which makes a protective layer around lyophobic sol. Hence, lyophilic sol are known as protective colloid.

B. Liquid-liquid colloid is also known as emulsion if they are partially miscible or immiscible liquids.

C. When $FeCl_3$ is added to hot water it lead to the formation of positively charged colloid.

D. When $NaOH$ is added to $FeCl_3$ it lead to the formation of negatively charged colloid.

Answer

A. $\rightarrow(2)$

B. $\rightarrow(3)$

C. $\rightarrow(4)$

D. $\rightarrow(1)$

Colloids are classified on the basis of types of dispersed phase and dispersion medium.

Answer

A. $\rightarrow$ (4) $\quad$

B. $\rightarrow$ (3) $\quad$

C. $\rightarrow$ (1) $\quad$

D. $\rightarrow(2)$

A. Purification of colloid can be done by dialysis in which ions/particles are removed from solution through semipermeable membrane.

B. Peptisation is a process in which when small quantity of electrolyte (peptising agent) is added to precipitate. It leads to formation of colloidal solution.

C. The process of removing of oily or greasy dirt from the cloth is done by emulsification.

D. Process of setting of colloidal particle is called coagulation. Electrophoresis is a process in which on applying electric potential to the electrodes dipped in sol, the oppositely charged particles of colloidal solution move towards oppositely charged electrodes, get discharged and precipitated.

Answer

A. $\rightarrow(4) \quad$

B. $\rightarrow(3) \quad$

C. $\rightarrow(1) \quad$

D. $\rightarrow(2)$

A. Butter is an example of dispersion of liquid in solid.

B. Pumice stone is an example of dispersion of gas in solid in which gas bubbles are pearced within solid particles.

C. Milk is a dispersion of liquid in liquid in which fats and protein are dissolved in milk.

D. Paint is an example of solid in liquid.

Answer

(c) Assertion is correct, but reason is wrong.

An ordinary filter paper impregnated with collodion solution stops the flow of colloidal particles because pore size of the filter paper becomes smaller than the size of colloidal particles.

Answer

(b) Assertion and reason both are correct, but reason does not explain assertion.

Colloidal solutions show colligative properties as colloidal particles have large size so colloidal particles have small value of colligative properties because number of particles are small in comparison to normal solution.

Answer

(e) Assertion is incorrect, but reason is correct.

Colloidal solutions show Brownian motion and this Brownian motion is responsible for stability of sols.

Answer

(a) Assertion and reason both are correct and reason is correct explanation of assertion. According to Hardy-Schulze law greater the charge/valency on flocculating ion added greater will be its power to cause precipitation.

Coagulating power $\propto$ Valency of flocculating ion

Answer

(a) Assertion and reason both are correct and reason is correct explanation of assertion. Detergents with low CMC are more economic to use as cleansing action of detergents involves the formation of micelles. These are formed when the concentration of detergent becomes equal to $CMC$. If $CMC$ has lower value then it will form $CMC$ easily and readily.

Answer

Catalyst is used to increase rate of reaction. Heterogeneous catalyst is used to increase rate of reaction in which catalyst is not in phase with reactants and products.

Role of adsorption in heterogeneous catalysis are

(i) Diffusion of reactants to the surface of the catalyst.

(ii) Reactants are adsorbed on the catalyst surface.

(iii) Occurrence of chemical reaction at catalyst surface.

(iv) Desorption.

(v) Diffusion of reaction products away from the catalysts surface.

e,g.,

Answer

There are various applications of adsorption in chemical analysis.

Some of which are as follows

(i) In thin layer chromatography The lower adsorbing particles comes out readily while another having higher adsorbing tendency comes out later. On this basis compounds are separated or analysed.

(ii) In adsorption indicators Surface of certain precipitate has an ability to adsorb some dyes to produce a characteristic colour e.g., AgX adsorbs eosin dye and thereby producing a characteristic colour at the end point.

(iii) In qualitative analysis Specific material has specific adsorption tendency so particular ion can be identified very easily.

(iv) In the separation of inert gases Different inert gases are adsorbed to different extents at different temperatures on coconut charcoal. This forms the basis of their separation from a mixture.

Answer

In froth floatation process sulphide ore is shaken with pine oil and water, the ore particles are adsorbed on froth that floats and the gangue particles settle down in tank. Thus, role of adsorption in froth floatation process can be understood as following processes.

(i) Adsorption of pine oil on sulphide ore particles.

(ii) Formation of emulsion takes place.

(iii) Froth is formed along with ore particles.

(iv) Mechanism of the functioning of shape selective catalysis.

As sulphide are extracted using froth floatation method therefore, only sulphide ore particles will show these type of adsorbing tendency.

Answer

The catalytic reaction which depends upon pore structure of catalyst and the size of the reactant and product molecules is known as shape selective catalysts. Zeolites are good shape selective catalyst because of honey comb like structure.

(i) They are microporous aluminosilicates with $Al-O-Si$ framework and general formula $M _{x / n}[(AlO _2) _{x}(SiO_2) _{y}] m H_2 O$

(ii) The reactions taking place in zeolites depend upon the size and shape of the reactant and product molecules as well as upon the pores and cavities of the zeolites.

(iii) Zeolites are widely used as catalysts in petrochemical industries for cracking of hydrocarbonds and isomerisation. They are also used for removing permanent hardness of water.

(iv) e.g., ZSM-5 is a catalyst used in petroleum industry

$$ \text { Alcohols } \underset{\text { Dehydration }}{\stackrel{Z S M-5}{\longrightarrow}} \text { Gasoline(petrol) (A mixture of hydrocarbons) } $$