Thermodynamics

Definition

It is branch of chemistry which deals with the heat energy change during a chemical reaction.

Types of Thermochemical Reactions

Thermo-chemical reactions are of two types.

1. Exothermic Reactions

2. Endothermic Reactions

1. Exothermic Reaction

A chemical reaction in which heat energy is evolved with the formation of product is known as Exothermic Reaction.

An exothermic process is generally represented as

Reactants ----> Products + Heat

2. Endothermic Reaction

A chemical reaction in which heat energy is absorbed during the formation of product is known as endothermic reaction.

Endothermic reaction is generally represented as

Reactants + Heat ----> Products

Thermodynamic Terms

1. System

Any real or imaginary portion of the universe which is under consideration is called system.

2. Surroundings

All the remaining portion of the universe which is present around a system is called surroundings.

3. State

The state of a system is described by the properties such as temperature, pressure and volume when a system undergoes a change of state, it means that the final description of the system is different from the initial description of temperature, pressure or volume.

Properties of System

The properties of a system may be divided into two main types.

1. Intensive Properties

Those properties which are independent of the quantity of matter are called intensive properties.

e.g. melting point, boiling point, density, viscosity, surface, tension, refractive index etc.

2. Extensive Properties

Those properties which depends upon the quantity of matter are called extensive properties.

e.g. mass, volume, enthalpy, entropy etc.

First Law of Thermodynamics

This law was given by Helmheltz in 1847. According to this law

Energy can neither be created nor destroyed but it can be changed from one form to another.

In other words the total energy of a system and surroundings must remain constant.

Mathematical Derivation of First Law of Thermodynamics

Consider a gas is present in a cylinder which contain a frictionless piston as shown.

Diagram Coming Soon

Let a quantity of heat q is provided to the system from the surrounding. Suppose the internal energy of the system is E1 and after absorption of q amount of heat it changes to E2. Due to the increase of this internal energy the collisions offered by the molecules also increases or in other words the internal pressure of the system is increased after the addition of q amount of heat. With the increase of internal pressure the piston of the cylinder moves in the upward direction to maintain the pressure constant so a work is also done by the system.

Therefore if we apply first law of thermodynamics on this system we can write

q = E2 - E1 + W

OR

q = ?E + W

OR

?E = q - W

This is the mathematical representation of first law of thermodynamics.

Pressure - Volume Work

Consider a cylinder of a gas which contain a frictionless and weightless piston, as shown above. Let the area of cross-section of the piston = a

Pressure on the piston = P

The initial volume of the gases = V1

And the final volume of the gases = V2

The distance through which piston moves = 1

So the change in volume = ?V = V2 - V1

OR ?V = a x 1

The word done by the system W = force x distance

W = Pressure x area x distance

W = P x a x 1

W = P ? V

By substituting the value of work the first law of thermodynamics may be written as

q = ?E + P ?V

The absorption or evolution of heat during chemical reaction may take place in two ways.

1. Process at Constant Volume

Let qv be the amount of heat absorbed at constant volume.

According to first law qv = ?E + P ?V

But for constant volume ?V = O

Therefore,

P ?V = P x O = O

So,

qv = ?E + 0

Or

qv = ?E

Thus in the process carried at constant volume the heat absorbed or evolved is equal to the energy ?E.

2. Process at Constant Pressure

Let qp is the amount of heat energy provided to a system at constant pressure. Due to this addition of heat the internal energy of the gas is increased from E1 to E2 and volume is changed from V1 to V2, so according to first law.

qp = E2 - E1 + P(V2 - V1)

Or

qp = E2 - E1 + PV2 - PV1

Or

qp = E2 + PV2- E1 - PV1

Or

qp = (E2 + PV2) - (E1 - PV1)

But we known that

H = E + PV

So

E1 + PV1 = H1

And

E2 + PV2 = H2

Therefore the above equation may be written as

qp = H2 - H1

Or

qp = ? H

This relation indicates that the amount of heat absorbed at constant pressure is used in the enthalpy change.

Sign of ?H

?H represent the change of enthalpy. It is a characteristic property of a system which depends upon the initial and final state of the system.

For all exothermic processes ?H is negative and for all endothermic reactions ?H is positive.

Thermochemistry

It is a branch of chemistry which deals with the measurement of heat evolved or absorbed during a chemical reaction.

The unit of heat energy which are generally used are Calorie and kilo Calorie or Joules and kilo Joules.

1 Cal = 4.184 J

OR

1 Joule = 0.239 Cal

Hess's Law of Constant Heat Summation

Statement

If a chemical reaction is completed in a single step or in several steps the total enthalpy change for the reaction is always constant.

OR

The amount of heat absorbed or evolved during a chemical reaction must be independent of the particular manner in which the reaction takes place.

Explanation

Suppose in a chemical reactant A changes to the product D in a single step with the enthalpy change ?H

Diagram Coming Soon

This reaction may proceed through different intermediate stages i.e., A first changes to B with enthalpy change ?H1 then B changes to C with enthalpy change ?H2 and finally C changes to D with enthalpy ?H3.

According to Hess's law

?H = ?H1 + ?H2 + ?H3

Verification of Hess's Law

When CO2 reacts with excess of NaOH sodium carbonate is formed with the enthalpy change of 90 kJ/mole. This reaction may take place in two steps via sodium bicarbonate.

In the first step for the formation of NaHCO3 the enthalpy change is -49 kJ/mole and in the second step the enthalpy change is -41 kJ/mole.

According to Hess's Law

?H = ?H1 + ?H2

?H = -41 -49 = -90 kJ/mole

The total enthalpy change when the reaction is completed in a single step is -90 kJ/mole which is equal to the enthalpy change when the reaction is completed into two steps. Thus the Hess's law is verified from this example. 

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Chemistry Chapter wise Objective
Thermochemistry test with Answers
    

Carboxylic Acids and amino acids

w.o.f amino acid is requird by the infants nd growing children

a arginine

b tyrosine

c phenylalanine

d a nd b

for complete reduction ov CN we need

a H2

B 2H2

C 4H2

C 6H2

trivial name ov 2-methylpropanoic acid is

a butyric acid

b iso.butyric acid

c acetic acid 

d propionic acid

-CN+H2O+H* ----->?

a amide

b crbxylc acid

b both

d none

for the oxidation ov aldhyds into crboxlic acids, the mild oxidizing agent is

a pottasium dichromate

b H2SO4

c ammonical silver nitrate

d both a nd b

aliphatic monocarboxylic acid r called

a faty acid

b amino acid

c both

d none

irritatiön caused by an ant bite is due to

a ethanoic acid

b methanoic acid

c propanoic acid

d butyric acid

CH3CL + KCN ----> CH3-CN --(HCL)--> X 

no ov carbn atom in x is ... Than starting alkyle halid

a les

b mor

c equal

non

formula ov palmitic acid is

a C15H31COOH

b C17H35COOH

c C15H30COOH

d C17H36COOH

c-c=c-c=c-c the oxidative cleavage ov dis molecule produce

a 2 ethanoic acid wd 1 oxalic acid

b 2 methanoic acid wd 1 ethanoic acid

c oxalic acid wd 2 methanoic acid

d 2 ethanedioic acid

w.o.f mlecule show oxidative cleavage

a CH3-CH=CH2

B CH3-CH=CH-CH3

C CH3-CH2-CH=CH3

D all

R'-COOR' + NaOh ------>A + HCL --------> X

wt is x?

a aldehyde

b ketone

c alcohol

d crbxylc acid

for cmplete reduction ov crboxylic acid, how many h+ r required

a 2H+

b 4H+

c 6H+

d 8H+

H2CO3 -----> CO2+H2 this proces is

a oxidation proces

b reductin

c simple decmposi in

d elimination

ethyne + H-OH ---(agso4 +h2so4 )---> X -----> rearangment---->Y --oxi--> Ch3cooh

x nd y is?

a x acetaldhyd

b y enol

c x enol

d y acetaldyhd

e both c n d

d both a n b

aldoenol tautomerism is shown by only

a ch3ch2oh

b ch3oh

c ch3ch2oh

d all

cmplete reduction ov CN produce

a immine

b ammine

c both

-CN + 2H2----->

a CH=NH

B CH-NH

C CH triple bnd NH

d all

in amine the hybrdizatin ov N is

a sp3

b sp2

c sp

d none

CH3COOC2H5+NaOH ----->CH3COONa + ?

a C2H5OH

B C3H7OH

C C5H11OH

D C4H9OH

first 4 eliphatic crboxylic acid r very soluble in water due to

a smal R.lenth

b large r.lenth

c h.bonding

d both a nd c

w.o.f compound has higher M.B 

a propanoic acim

b butanoic acid

c methanoic acid

d pentanoic acid

ethanoic acid + NaOH ----> Na.acetae + water

dis reaction is an example ov

a electrophilic substitutin reactin

b nucleophilic s.reaction

c salt formatio

d a nd c

e b nd c

-COOH+ 4H ----> -CH2-OH catalyst?

a Na

b riny Ni

c LiALH4

D P

CH3COONa + HCL-----> ?

a new salt + new acid

b new salt + salt

c acid + acid

d none

crboxylic acid + metals ---> ?

a new salt only

b new salt + new acid

c new salt + hydrgn

d none

butyric acid was named aftr the butyrum means

a ant

b vinegar

c butter

d none

in partial reduction ov carboxlic acid the change in hybridization ov c

a sp2 to sp3

b sp2 to sp

c sp3 to sp2

d no change

corboxylic acid gives Nü.S.reaction with

a Na

b Na2CO3

c NH2

D NaOH

if wolf.kishner rductin is started wd carboxylic acid, how many hydrogen atms r required to get the final product

a 4

b 6

c 8

d 2

esterz are formd in the presnces ov .... H2SO4

a concntrate

b dilute 

c v.dilute

d v.conc.

requre temp for aldol tautomerizm is

a 90

b 80

c 70

d 100

when corboxylic acid react wid corbonates nd bicrbnates they produce

a önly H2O 

b only CO

c carbonic acid

d none

acetic acid + acetic acid ---P2O5--> ? 

resulting product cntain no. Ov crbn

a 4

b 6

c 8

d none

-COOH + 4H ----> CH3OH

shows

a oxidatin

b cmplete reductin

c elimination

d none

2CH3COOH + Na2CO3 ----> ?

A new acid + new salt

b new acid + new acid

c new salt +n.sal 

d none

during esterification w.o.f proces is observd

a polymerization

b condensation

c elimination ov H2O

d all

during esterification ov crbxylic acid the net deprotination is

a 2 

b 4

c 1

d none

during esterification change in hybridizatin ov c is

a sp3 to sp2

b sp2 to sp3

c sp3 to sp

d no change

no. ov enzymes require to prepare ethyl alcohol frm molasses

a 1

b 2 

b 3

d 4

enol/aldol tautomerism is shown by

a ethanol

b propanol

c butanol

d none

we oxidized .... to prepard aldehyd is

a rectified spirit

b absolute alcohol

c both

d none

acet amid can be prepared directly frm

a acetic acid

b propionoic acid

c formic acid

d can never prepare directly

acet amid can be prepared directly frm

a acetic acid

b propionoic acid

c formic acid

d can never prepare directly

a food chemist wants to create the odour ov pineapples for a product. an ester with odour has the formula C3H7CO2C245. which pair ov reactant would produce dis ester

a C245CL nd C3H7CO2H

B C3H7OH C3H7COCL

C C2H5OH C3H7CO2H

D C3H7OH C2H5CO2H

w.o.d in equeous solutin ov equal conc. has the lowest pH

a chloroethanoic acid

b ethanoic acid

c ethylamine

d phenol

amino acid that cn't be synthesized de novo by the organism

a esential

b non.esential

c basic

d none

hydrolysis ov CH3CH2CN wil synthesize

a ethanoic acid

b propanoic acid

c methanoic acid

d glutamic acid

w.o.f is stronger acid

a CH3COOH

B CLCH3COOH

C CL2CHCOOH

D CL3CCOOH

w.o.f isomerism is nt shown by crbxylic acid

a chain isomerism

b functinal isomerism

c positin

d optical isomerism

if NaOH is aded to an unknown organic cmpound nd the reactin envolves NH3 then this unknw cmpound is mst likely to b

a an ester

b a crboxylic acid

c an acid amid

d an alkene

the strength ov the organic acid nd chloro substitutd acid is measured by pKa scale such that the smaler value ov pka corespnds to

a strongr acid

b weaker acid

c mild acid

d very weak acid

hydrolysis ov amides undr acidic or alkaline cnditions gives

a same product

b difrnt product

c smtime a nd smtime b

d none

during the 4mation ov an acid amid frm ethanoic acid wt actualy hapns

a displacment ov H frm the acid by cl

b dsplcment ov OH by NH2

c dsplcment ov NH2 BY crbonyl oxygen

dislcment ov H by NH2

salt ov crboxylic acids r prepared undr

a acidic cndition

b alkaline condition

c neutral cnditin

d none

acetic acid can be prepare by ethanol undr

a oxidizing cnditin

b redox

c reducing

d 0.7 pH

alanine is an amino acid bt its nature is

a acidic

b basic

c nutral

d none

during peptide 4mati, cndensation polymerization ov ... functinal group take place

a1

b 2

c 3

d none

the basic chrctr ov nutral amino acid is due to

a amino group

b crbonyl group

c carboxylate group

d none

if ethanoic acid is to be prepared by thy hydrolysis ov alkyl nitriles, w.o.f can be the reagent to be hydrolyzd

a CH3CN

B CH3CH2CN

C HCN

D none

an organic cmpound X is prepard by the oxidatin ot ethanöl. This x reacts wd ethanol to produce ester. Wt x likely to be

a ch3cOOH

B HCOOH

C CH3CH2COOH

D any crboxylic acid

an organic cmpound X is prepard by the oxidatin ot ethanöl. This x reacts wd ethanol to produce ester. Wt x likely to be

a ch3cOOH

B HCOOH

C CH3CH2COOH

D any crboxylic acid

Ethyl acetate + NaOH ------> sodium acetate + y

wt is y?

a methyl alcohol

b ethyl alcohol

c aldehyle

d none

Ethyl acetate + NaOH ------> sodium acetate + y

wt is y?

a methyl alcohol

b ethyl alcohol

c aldehyle

d none

in zwitter ion acidic chrctr is shown by 

a NH3*

B COO-

C BOTH

D non

lactic acid is

a propionic acid

b ß. hydroxy propionic acid

c alpha hydroxy propionic acid

d none

galcial acetic acid is produced at

a 18

b 17

c 16

d 20

carboxylic acid --X--> alpha.halocrboxylic acid ---NH3--> C

c is?

A aldehyd

b ketone

c amino achd

d none

a clrles organic cmpound gives brisk efrvescence with a mixture ov NaNO2 nd dil.HCL it could b

a glucose

b glycine

c oxalic acid

d benzoic acid

the amino acid lacking a chiral carbn

a glycine

lysin

c proline

d alanine

CH3COONa is trated wd .... HCL to give carboxylic acid

a concntrated

b dilute

c very dilute

d vry concentratd

after the partial reduction ov -CN the resulting product is

a CH=NH

b CH-NH 

C CH triple bnd N 

d all

CH3-C (Triple bnd) N is calld

a methyl nitrile

b ethyl nitrile

c ethyl cyanide

d both a nd b

trivial names ov carboxylic acd r derived from .... hving same no ov c as that acid contain

a alkanes

b alkenes

c alkynes

d alkyl halids