8.9 Stability and coagulation of colloids

8.9.1 Stability of colloids

Colloids, a dispersion system with high specific area and

thus high interfacial specific energy, is thermodynamically

unstable. Collision between colloidal particles frequently

occur and aggregation is always a possibility.

8.9 Stability and coagulation of colloids

Stabilizing factors:

(1) Dynamic stabilization: Brownian motion and diffusion

prevents colloidal particles from sedimentation.

(2) Electric stabilization: All the colloid particles in a

particular system have the same charge tends to repulse each

other and keep the colloid in suspension.

(3) Solvation shell: The interaction between particle and solvent

also helps to prevent aggregation of colloidal particles on

collision.

8.9.1 Stability of colloids

8.9 Stability and coagulation of colloids

Electrolytes As2S3 () Electrolytes Al(OH)3(+)

LiCl 58 NaCl 43.5

NaCl 51 KCl 46

KCl 49.5 KNO3 60

CaCl2 0.65 K2SO4 0.30

MgCl2 0.72 K2Cr2O7 0.63

MgSO4 0.81 (KOOC)2 0.69

AlCl3 0.093 K3[Fe(CN)6] 0.08

Al(NO3)3 0.095

Precipitating value:

The lowest concentration of electrolyte ( in mmol dm-3) at

which precipitation of colloid can be easily observed.

8.9.2 Precipitation of colloids by electrolytes

8.9 Stability and coagulation of colloids

8.9.2 Precipitation of colloids by electrolytes

8.9 Stability and coagulation of colloids

Precipitating value and precipitating efficiency / power

The ion which is effective in causing precipitation of a sol is the

one whose charge is opposite to that of the colloidal particles, i.e.,

counterions

(2) Hardy-Schulze rules.

(1) Valence:

the higher the valence, the lower the precipitating value.

6 6 6

I II III 1 1 1M : M : M : : 100 :1.6 : 0.3

1 2 3

is only valid without specific adsorption.

The precipitating efficiency of morphia (I) chloride is larger than

Mg (II) and Ca (II)

8.9.2 Precipitation of colloids by electrolytes

8.9 Stability and coagulation of colloids

(2) radius

Hofmeister / lyotropic series

H+ > Cs+ > Rb+ > NH4+ > K+ > Na+ > Li+

F- > Cl- > Br- > NO3- > I-

(3) co-ions

When counterion is the same, the higher the valence of the

co-ions, the higher the precipitating value.

Electrolytes KNO3 ½ K2SO4

Precipitating values 50 65.5

Precipitating values for As2S3 colloids

Fe(OH)3 sol + HClNonregular aggregation

8.9.2 Precipitation of colloids by electrolytes

8.9 Stability and coagulation of colloids

Aggregation of sols by electrolytes

1) Preparation of soy-bean curd.

2) Detoxification of heavy metal ions

8.9 Stability and coagulation of colloids

8.9.2 Precipitation of colloids by electrolytes

3) Formation of delta and alluvion

When the river water containing colloidal clay flows into the sea, the

brine induces coagulation. This is a major cause of silting in estuaries.

Aggregation of sols by electrolytes

8.9 Stability and coagulation of colloids

8.9.2 Precipitation of colloids by electrolytes

8.9 Stability and coagulation of colloids

8.9.2 Precipitation of colloids by electrolytes

8.9 Stability and coagulation of colloids

8.9.2 Precipitation of colloids by electrolytes

Now the seashore of Yancheng City is 15 kilometers away.

8.9.3 mutual precipitation of colloids

Generally, mixing of colloids with the same charge does not

lead to precipitation, while mixing of colloids with different

charge will result in mutual precipitation.

Fe(OH)3(3.04 g dm-3) 9 8 7 5 3 2 1 0.2

As2S3(2.07 g dm-3) 1 2 3 5 7 8 9 9.8

charge + + + + 0 - - -

phenomenon --- Turbid ---

Purification of water using alum

8.9 Stability and coagulation of colloids

8.9.4 Coagulation – precipitation by polymeric electrolyte

Coagulation is the process of adding chemicals to water to

make dissolved and suspended particles bind together

(coagulate) and form larger particles (flocculant) that settle

out of the water.

Aluminum sulphate, ferric sulphate, ferric chloride, and

forms of aluminum or iron salts called polymers are all

suitable coagulation chemicals approved for water treatment.

8.9 Stability and coagulation of colloids

(1) effect of macromolecules on colloids

1) Stabilization effect:

When lyophilic sol, such as gelatin, albumin, agar, casein, gum

arabic, glue, starch, etc. is added to a sol, the latter may be

prevented from precipitation by electrolytes. Such

macromolecules are named as stabilizing agent or stabilizers.

The macromolecules adsorbed on the colloidal particle form a

tough shell which helps to keep the particle apart.

8.9.4 Coagulation – precipitation by polymeric electrolyte

8.9 Stability and coagulation of colloids

Gold number:

The number of milligrams of the protective colloid that just

prevents the change of color when 1 cm3 of the standard salt

solution (10 % NaCl) is added to 10 cm3 of the standard gold sol

(0.006 %). (By Zsigmondy)

Protective colloids Gold number / mg

Gelatin (明胶) 0.005-0.01

Albumin (白蛋白) 0.1-0.2

Gum arabic 0.15-0.5

Dextrin (糊精) 6.0-20.0

Potato starch 25

Red number: Congo red

8.9.4 Coagulation – precipitation by polymeric electrolyte

8.9 Stability and coagulation of colloids

2) Sensitization effect:

When small amount of some lyophilic sols was added into a

lyophobic sol, the sol can be precipitated by less amount of an

electrolyte. In other words, the addition of the lyophilic sols

decrease the precipitating value of the sol. This phenomenon is

named as sensitization.

The recoil of the macromolecules helps to draw several

particles together.

LaMer: Bridging effect

8.9.4 Coagulation – precipitation by polymeric electrolyte

8.9 Stability and coagulation of colloids

Flocculation of colloids:

flocculants

Chemicals by adding which

suspended solids in the

wastewater are sedimented

and clearized water is gotten.

Kinds of flocculants:

1. inorganic: polyalminum chloride

2. polymers: polyacrylic acid, polyacrylamide derivatives

3. naturally occurring flocculants: chitosan, sodium arginate

8.9.4 Coagulation – precipitation by polymeric electrolyte

8.9 Stability and coagulation of colloids

Polymeric electrolyte – polyacrylamide (PAM)

M > 106

-[- CH2 – CH-]m-

C=O

NH2

Differences in flocculation and aggregation

flocculants are widely used in water treatment plant, pulp

industries ,the food industries and so on.,

8.9.4 Coagulation – precipitation by polymeric electrolyte

8.9 Stability and coagulation of colloids

The electrolyte causes a compression of the diffusion layer

of the double layer and decreases electrokinetic potential,

which allows two particles to make a closer approach to each

other.

8.9.5 DLVO theory

6 6 6

I II III 1 1 1M : M : M : : 100 :1.6 : 0.3

1 2 3

8.9 Stability and coagulation of colloids

Around 1942, Deijaguin-Landao-Verwey-Overbeek

1) The inter-particle attraction: long-range dispersion forces

x

aHVa

12

222

03

4nhH Hamaker constant

2) The inter-particle repulsion:

x

r eKTn

V

22064 Debye-Hückel

constantkT

en

2

08

xa

r erKV 00

8.9.5 DLVO theory

8.9 Stability and coagulation of colloids

The inter-particle potential

x

aHerKx

xa

12)( 00

Interparticle potential curve Potential curves for colloidal systems

with different .

x

E

0

x

E

0

62

453

cZH

rkTC

)(

8.9.5 DLVO theory

8.9 Stability and coagulation of colloids

As the concentration of electrolyte

increases, of colloid decreases.

When = 0.03 V, colloid begins to settle.

When = 0, precipitation rate attains

maximum.

/V

0.03 0.00

r

c/mmol/L

8.9.5 DLVO theory

8.9 Stability and coagulation of colloids