States of Matter (JEE ADV.) Notes PDF

Summary

These notes cover the fundamental concepts of states of matter. Topics include the three states of matter (solid, liquid, gas), the factors that influence the physical state of substances, intermolecular forces, and different types of intermolecular forces like dipole-dipole interactions, dipole-induced dipole interactions, and London forces.

Full Transcript

STATES OF MATTERts
(JEE ADV. )

Introduction

Mater exists in hree physital states
13Solid

C3)Ghas
10
The phy sicql state oF substances depend on:
stote
CJ Interparicle torces of attraction increases’ Solid
2J hermal energy inCreases’ G9seous state

When inter-parile forces of attraction increases and thermal
decreaseS andsUbstance
15
energy decreases, intereparticlel distance
will exist inSolid state.
When inter-paricle torces of attrachon decreases and thermal
energy íncreases, interiparticle distance increases and substan ce
will exist in qaseoUs state.
Hgh temperature ond lou pressurer are favourable conditions
for qaseOUS State.

Intermoleculqr forces of Attraction
ethootit eg
These are weak forces ot atraction withaut any strong bond
They are electrOstatic in nature and are called as yan der
waal's forces'

TYPES OF VANDER DER WAAL'S FoRCES nob n03
Dipole -Dipole interaction
2J Dipole -induced dipole ioterachion t ty
6J Tnstontaneous dipale interachon (London Forees IDispersion öre)
 Date

LIJDipole - pipole in teraction T8

hese forceseist in pol ar molecujes Qnd are alsó CQlled
as kusom forces
5
Example3
æ) HCL
H- CL H- (L
>dipole - dipole interachon bioL
n Stah on ary polar molewles (Solid):
10

SPbloDipole-Dipole Inter actión o t sroan9ta L1

C23 rotating polar moleules (Iiquid) :

e Dipole-Dipole tnteraction

Dipole - Induced Dipole Interaction

2o These interactions exist behueen polar and non polar moleules
Example:
Ci)
---Neoo 4 0 29)X oo9Bom7
dipole- induced dipole interachon

Dipo le -Induced Dipole Interacion p9

C33 London forces or Disperston forces 302321I

These exist In non -polar. moleculesht it
Distribotion of electrons is not Symmetricalati all times
in moleules,
 Dute:

0r some insBant. more electrons are gatheredon one side
oF the moleule and produce instantaneous polarits.

uniform dist1bution binstantaneous interaction
of elechrons
Examples

tiD Caraphite layers (iv) T2
40

nstan taneous (nteraction i

JDENTIEYIN G THE INtERA CTLONS TMU

15

a p 3 0 2 3 1 0 Ti dO3
NacCand NaCc

Ng cLT Nat c lon - lon
jonion interachon Interacion

2] Na CU and H20

Ng lon - Dipoleio l
Interacion F r
O-H8+
HSt

C3] NOz andT2 will have' ion - induced dipole interacthion

H-cu'----H
dipole -dipole interaction
 Dote :

Q.Exercise 6.
A[6J ()iton cion> ibn +dipole > dipole - dipole

tJC2)-Londoh disp ersion and dipole -dpoe
5

Pressure
ressure is the amount of force applied to Qcertain
aY ea
10
Unit - NÍm Pressure =, Force
yo Area
k /msO
Pasca (Pa)

SI UNIT OF PRESSURE= katms Pa
15

CoS ONT DF PRESSURE = qn /Um s 1Dynelm CD
Barytte (Ba) =0.1 Pa

bar9.8692 x 0 atm = 5x\0
20 torr
(onvert the following units NOTE
-5
() 4 bar = 10 Pa & torr = mm of Ha
() 1 atm =iI325 Pa A atm = 60 mm of ta
(w) 4 atm 1.0|325 bari!
25 (ív) 4 Qtm = 60 torr

IMEASURIN GPRESS URE : 760 Mm =16 cm
qtn ato fisofopic)
30

BAROMETER
Neruny(hg)
 Date:

We know that
P=F

P=Ax hx Px9

P=h9 where h= height, R= density9grauty

MANOMETER
Pgas > Patm

G,AS Pgas
Hg Cmerury)

Yqas

GaseouS Laws

L Bole'sLawrelatión be hoeenPand V, at constant n and T
[23 Charle's Law ’relaion bekween yand I, at constant n and P
Lus sac's Lauo ’relahon behween Tand P at constant n and V
[u] Avogadro's Law>relaion behween N.and n, at tonstant v and n

Boyle's Charlels Gay- Lussao's Avogadro's
Law Law

V n.
 Dote

Boyle's Law

The volume of a qiven mass of a qas is inyersely
proportional to pressure
pr at constant temperature

P

10
It means that. gases are compressible. On incre asing
pressure, their volume decreases and qases occupy less volume
Than eorlier As interparticle distance decreases , density inrease
PV = K
P
151
Initial state i Final Stqte : from eaations ()and (e
Pv =k->)

Pi: Pt V+dt
Vi

K

constan t
As 9Va k, app lying og 0
2s 9yo)
ChRAPHS of BoYLE'S LAW :

P Vs V

30
P
P

V
 Date

CuJ log P vs 0g V
(oJ PV vs P Jog Px (0gv t k
1
py log P

P log V

Charle's Law.

The yolome of a given mass of gas is directly proportiona
10| its absolute temperature at constant pressure,? a

V=k,T

15

Inítia State i Final sate: from eaahons (0 and (2)
V, k - ’ )
T2 V2 T2

T
20

log v - loq T 3 k ’\09 v= loq T t k ) yv!

Experimentally, it is observed that for each deqree change ot
temperature, the yolume of qas changes by a fraction ot
273
of its vol Ume at 0'C.

273

> V Vot No XT
273

L+T
273

VT |T 273 t Tet
Vo 273 273
 Dato:

GRAPHS OF CHARLE'S LAW
CJ Vvs T (kelvin) 2] v ys T (celciuS)

T (K)-+ T()

13), log V vS Log TG Cu]VT VS T
4veslope
log V3lxlog T + k
logv

T
15 log T

Giay- Lussac's Law

The law States that at constant volomethe pressUre ot
20 a Fixed mass of a gas is directiy proporhiongl to the
kelvin tempera t o r e Ypi

PT|

25
P
T

lnitiql Statei Fingt State Lfrom eajuations ) iand )
T Ly (2) P2

a As P k applying log

Jog P- Jog T = k >hog P 10g T tk
 Date :

(uRAPHS OF CAY LUSSAc's LAW:

P vs T
aI C2] leg P ys log T.
Jog P logTtk
og: P yzmntc)

lo9 T

Cu) P vs (T

T

o

[4J Avog adro's Lawot
25

TE We add more amoun oF qas at constant temperature
and pressore in aoballoon (ontaining 'qcertain MasS of
gas, then volume of qas wíll incra Se.

V=n k ’
 Date:

Initial state : Einal Stqte: From eauahons (0 and (2)
=k
n2 n2 V2
n2

ts Tuis Is the base of Avogad ro's tauw which states that i
Eyual volumes of all qases at same temp erature und
pressore Contain eayual humber of molewles

ldeal Gioas Eqjuation.
10

On combining Boyle's lauw, Charle's law and Avogadro's_ law, we
9et an eauation Known as the ldeal gas, eayuation.
we get:
Boyie's Law v I ’V nT
P nRT
where
Charie's Law’ vdT R is the úniversal
Avogadro's Law ’ V«n 94s constant
NOTe THE FOLLOWINGG:1

hT

20
at STPPF1 atm T60mm ot H 760 torr =.0|33 bar
UNI TSoF R
atm X litre EL:atm. k mol
moi x k

when P=latm, V= 22, 4L, n =lmolT=0c = 243K
28 then R= 0.o821 L. atm. k mo
fP li0133ban,M0
thenR=0.0331L bar. mol
=8.3)4 JkI' molo siN
-3
kJ. kmol
30
8.314X 0 erqi
k mol
2 Cal. k mol
NOTE : 1 L bar = 10|.32 3|
 oTHER FORMS OF IDEAL CAS EQUATION :

PV nRT is the ideal gas eauation,.
as 9tven mass
molar mass

Pv= w RT PM = WRT
M

P= dRT ’ PM E JRT O’d= PM
M TIRT

10
(s)
Combined Gas Law

This law is a com bination of Boyle's law and Charle's Lau.
Boyle's LQw > V L
P

Charle's Law Va T PV K= Constant

Inihal state : Final State : Fom payvahons (D and C2)

20
T.

GhßAPHS

C23
P
25 P
P
P
t

-273°c oc

R>P Pg>Py.T) T2) T; >Ty >V2>Vg P, < P2 P2 >P3

-
T (pnstqnt
M

T
STEP 2 + Q s o S M
A. PVRT
F1o PV w RT
M
PM =dRT

Cons tont (2)

Dalton's Law of Partial Pressure

Ihe totapressore exerted by a mixture of non -reàcting
20 qases is eqyual to the sum Dt parhial pressure of each

99s present in the mixture
non -reating qacesAB and C
at constant t and v

According to ideal gas eQuation :
PV nRT

For Ghas A: For has Bi For nasC:

Substitutng these values in eqyuation C0 :
 > P r ART
V V

PrCna t notne) RT (2)

Dividing Pa by eyuahion () :
DA

Pr na tne tnc (V)
Pe = g. PT
PA

10 Pressure of dry gas = Pmoist g4s -Pwaervopovr
= Pmoist qas Aayveous tension
no water invol vement

Exercise 5:|
PL E V2)’ 2 0 0 ’ Pe 5 2. 5 atm
P2 Vi P2

(3) =2.5 atm9 91

[23 Na pour density E Moleolar weignt ozmolewlar weight
2 2

L4o moleular werqnt

(3) =5

[3J No. of moles of Co uy.0:lmoles

hiven volumeoe 0be iven vol ume o.X22.4
22.4 2.2y

C2) 2.24L

’ 5.3 X= P2 ’ P2 5.3 XtO
|0YhooFS3 atm
 Date :

(3)= 53 atm

Ha no9 2 --Co2 >n9E22=0.S
m

s He >n 9 = 2 m 32
m
4

)He
T
L8)) =A is alse but R is true
10

Kínehc Theoryi o£ Ghases
POSTULATES &
he q9seous moleules are conSidered to bepointm9sses
L The volume oF a molecule is neqliible as compared to totel
volume of the qaS
C3] The mslecules neither attract nor repel each other
4JThe collisions qYe perfectty elastic,i.e there ís no loss of
enerqy duing the mole cular collísions
15 The average kinetic energy oE molecules is directly proporiong
to the absolute temperature of the qas.lla
B] The effect of qravity on molecular motjon is heqigqible.

KineticGhas Eajva thon
25

Py = mnurms where m’ mass of lmolewle of gas
n’ nUmber ofmolecules of
Urms> root mean sauare speed of molewev R

30 Urms =/u2 +u tu +un
n

E n Avogadro's number =6.022 x?5
 Dale

m XNe molar mass (M)
mx NA X Drms (l mole)
3

PV=2 X X m x Ng XUrms

3 2

k.e. =3 PV but PV n 2 T ’ PV = T x Na
2

K.E. = 3 XRTY I
2 Ne

Molecular Speed in Ghases

CU R00T Me AN SOUARE SPEED

IE there are n particles having'speed u ne particles'having
Speed U2 and so.
othen Urms=
n tn2tn3t

Urms 3PN 3P
M M

(23 AvERAGE SPEED:
’Uay
n t h t n3 + M.
RATIO
Ump:V av:Urms
C3 MoST PROBAGLE SPEED!
Ump = 22T 22T
M M M M

= 1:. (28 224.
Urms > Uqvg > Ump
 Date

Maxwell Boltzman Dístribution Corve
df
Fracton
molecules

Uavg.
Urms
On increasing temperature
pealk becames broad and
shifts towards the

10 Molecular Speed ’
Fbr
mati
o Motelutes
ctzt1g) qt 300k

N2(sg)
2920r C2 mass Ne mass

15

Molecular Speed’

Grahamn's Law ot Difusion:

Acording to Ghraham'si law,At tonstant pressure Qnd
temperature, the rate of difPusion or effusion of gas
a is
inversely proportional to the saju are root of its vapour
or molecular mass
density
25

and r2 I

30 r

Vix t2 m2
ti V2 V m

PvnTv
 Dgie :

n mi

Eyerise 5.2 2103l2 tit
ACA 0 3 Is proportional to temperature
|3RTH2
UH2 MH2 Also, H2 =VtUN2
3RTN2.
UN MN2
(2) = TH2 > Tu2iov yiotnt rv

Behav iour of Real Ghases

Agas that obeys the ideal qas eqyuahon at all t mperature
and presure is called as ideal gas. But prachcalty
deal.
So, the non-ideai qases or real qases are actualls qases which
Obey theiaeal qas eayuation at loo pre sSure and hgh.
20 temperature
According to ideal q9s eajuation Pv =nRT0
tot) PV=2’ (ompressibil1ty
nRT factor

A plot of z VS P at tonstant tmperature shows 'deviahion
2s fYor ideaV behaviour.

at constant
CO2
temperature
2= PV Te qas be haves idealty,
ideat as
PV
nRT
 Date :

CAUSES of DEVIATION:
Actually. g95 Moleules do oCUpy some volume and it_cannot
be neglected.
OTheir must be either attractive or repulsive fores beween
5
gaseous molecules
C3)
So byCorrecting these too postulates oF kinetic theory of qises
We can qet a new eayua 1on
Pv e nRT ’ideal gas eqyuation
PV 2 t n= 1 Mole 2= Pv
10
nRT

2 Vm (real) where Vm molar volume < T E
Vm Cideal) CiE changes due to attraction between molecules)

Prssure Correction attraction
15

rep
3204a ldeai Ghas Real Gas Pi =Pt P!
where, y22910 al O
20 p>observed pressue of he qas
Pi> ideal pressUre of the q9s
altd P> pressure correction (loss in P dye to intermolecular form
of qtrachon)

where a is vander-waat's
25 uConstant9bi
Pi= p+ Units of a =atm.L mol

Volume Corretíon
3

ldeal qas assumes molecoles to be point masses. but at high
pressure, yolume of qas mole coles cannot be neglected
If ViS the volume of Container
 Date :.

then nb ’volume whch is incompressi ble Qs molewles are
penerable spheresgAu
So, (orrected yolume wilL be as foliows3ot
|Veorrec ted =Vnb where 'ois yander-waal's constant and.
sLnis the nom ber of moles.
(orrected ideal qas eajuation which is called as yander -waal's

20Vqnder- waal'sP t an (Vnb)=nRT.
Eyuation
vicinity hel Nolume of A molecule =Volume of sphere =4TY
3
4n2r) Cinduding impenetrable
sphere)

7 for only moleculeilat_ iatPLL
2

Exercise 5.2
A.C03) m
Since No is injected with a
NO 2 o0 9redter press ure than O,it
24tm +latn
wil cover more distance in the
e tube.
Pressure 2:1 Oxygen will over One - third of the

-o.33..

(2) = 0., 33 m. 2920rd0 noitetiopi!

Compressibility Factor (2) :293T344909 34FS)
 Date

[CASE
4J2=1’ ldeal Q9s eyvstion is folt owed for all temperature
and pressure.
LCASE 23|2~| ’At
At low pressure, real gas behaves Idealy due to
very few intermoleular at ractive forces
Cse 2 At hiqher pressure particles of qaseS will Come
Lcleser Qnd there will be strong tnterpartkle
attractive forses (tue deviahon) Gnd repuls1ve forc eg
will become acthve we wit! qet volume more than
ex pected.
CRSE 9J2 ) T4 Vt foAt Tideal
25 below,Te -ve deviaion (2 esily gas OSurfa ce area +
27Rb wil be liquihedo molar mass
Nander-waal's forces ‘

C2J Cniticat Pressure IH is he minimu mpressUre thatis
5
resyured to liqyuifya gas at crctical tenm perature
Pe =
27b2

C33Criticqt yolunme - Volume occupied by gs at le ane
10 VE3b

COMPRE SSIB1LTY FACToR AT (RITICAL CONDITION

neT

a
b

27 Rb 27b

Andrew's Iso thfrm curve

uidLi 48°c
35.5° C
2°c10 9 tsotherm eurve
Ghas rU229 0f Co2
M 21.5¬
shouing
cratiareqsn
)'00Nolume

Liajvid State

EVAPORATIÛN Itis a protess ot change o liauid into
Vopoyr state at any given temperature.
 Date:

evap oraton, cooling occors ds qverage Kineh energy ok
remaining malerules decrease.
The rafe of evaporton depends on intermolecolarforces
Slower will: be the rate of evaporathon.
5

Rate ofe Evaporation d Surface Area Te mperature

Vapour Pressure

1E is the pressure exerted by vapour on its surface at
eauilibrium.

Rate of Condens ation Rate of Evaporation
dynamic eqyuitibr iurm
15

(zlis0gH5 CMs0H H20
4otm

3416C 8.5°c
20

Boiling Pont

The temperature at whiCh vapour pressure becomes equaL to
25 atmas pheric pressure.
for H0
Standard boiling point at 4 bar = 99.6'C
Normai boiling point at 4 atm = lo0°c

Clausius (lopeyron
log P2= AH
Pi 2.3032
 line
any qradíent
to
Date anqles
decreQses. cosíty viscosity
nn
right ’vis
tlow of
at area
dy (oeficientt
ce S=f
Nm Surface the unit
poise ln)
surfa where,
resist
sion, neta
the ’
to neta of
on ten liauid F-n Nm
Surface
Tension Adv reciprocql
Tne
tore
achng
ok
unit
lenqth Surface o.
Viscosityof
Property =
Fluidity
Poise
to is
Due It
4
15 20
2