Polymer Properties Exercise 3
Jan 17, 2016
Polymer Properties
Exercise 3
1. Crystallinity and DSC t (s) Xt
0 020 0.002660 0.0383
120 0.1947180 0.4454240 0.6988300 0.8753420 0.9916600 1.0000
DSC curve for melting of iPP
Hf=92,95 J/g
Heating
10oC/min -->
Tm=166,2oC
18
20
22
24
26
100 120 140 160 180 200T/oC
En
do
ther
mal
hea
t fl
ow
W/g
nkttX exp1
Heat of fusion for fully crystalline polypropylene is 209 J/g.
Avrami equation:
Crystallinity of isotactic polypropylene was studied with DSC. Melting enthalpies (Hf) were used to obtain the values for relative degree of crystallinity Xt. Calculate the degree of crystallinity for isotactic PP and determine the constants n and k for Avrami equation. What can be said about geometry of the crystals based on the Avrami constant n?
1)• Degree of crystallinity can be calculated from the measured enthalpy data
of isotactic PP Hf and melting enthalpy of completely crystalline PP:
• Solving the constants from Avrami equation it needs to be manipulated for the form:
nkttX exp1
0
92.950.44
209
f
f
JH g
XJHg
1 exp( )
ln(1 )
ln( ln(1 )) ln ln
nt
nt
t
X kt
X kt
X k n t
1)• By plotting ln(-ln(1-Xt)) as a function of ln t, constant n is obtained from
the slope and ln k is the cross point with y-axis.
• From the figure n = 2.44 and
t (s) Xt ln t ln(-ln(1-Xt))0 0 - -
20 0.0026 2.9957 -5.955560 0.0383 4.0943 -3.2420
120 0.1947 4.7875 -1.5299180 0.4454 5.1930 -0.5284240 0.6988 5.4806 0.1822300 0.8753 5.7038 0.7333420 0.9916 6.0403 1.5644600 0.9999 6.3969 2.2203
3 3.5 4 4.5 5 5.5 6 6.5
-7
-5
-3
-1
1
3
f(x) = 2.43577962090168 x − 13.2090680077249
ln t
ln(-
ln(1
-Xt)
)
-6ln =-13.209 =1.8 10k k
1) Avrami constant• Derived Avrami exponents for different nucleation and growth
mechanisms:
• Based on the Avrami constant n =2.44
The sample would contain two types of crystalline structures, depending on nucleation at least disc-like crystallites.
2. Characterization of a mixture• In quality control the analysis has to be quick and easily repeatable. A
small amount of antioxidant Irganox 1010 was added to PE in the production. The amount of the additive was followed with UV spectroscopy. For the reference a set of samples with the known amount of antioxidant (0-0.1 mol-%) was measured:
a) Use the measurements to formulate a correlation in the form A(c,t) = (kc+a)t, according to Beer-Lambert law that can be used to determine the amount (c) of antioxidant (AO) in PE sample. Thickness (t) of the sample as well as the UV absorbance (A) is measured.
b) Use the equation then to determine the amount of antioxidant in a PE sample with thickness of 0.4 cm and UV absorbance A = 0.61.
AO 0% AO 0.01% AO 0.05% AO 0.1%t / cm A A A A
0.1 0.042 0.081 0.29 0.57
2)• Beer Lambert in general:
• Use the measured data to construct an equation following the Beer-Lambert law in the form:
A(c,t) = (kc+a)t
• When there is no antioxidant in PE, cAO = 0, t = 0.1 cm, and A = 0.042, we get:
• In order to get the constant k, A/t must be plotted as a function of c so that the starting point for the plot is c = 0, A/t = 0.42 cm-1.
A kct
10.042(0,0.1) ( 0 ) 0.1 0.042 0.42
0.1A k a cm a cm
cm
AO 0% AO 0.01% AO 0.05% AO 0.1%t / cm A A A A
0.1 0.042 0.081 0.29 0.57
2) c A/t0 0.42
0.0001 0.81
0.0005 2.90
0.0010 5.70
0 0.0001 0.0002 0.0003 0.0004 0.0005 0.0006 0.0007 0.0008 0.0009 0.0010
1
2
3
4
5
6
f(x) = 5205.55555555556 x + 0.42R² = 0.99889818257825
Determination of constants
c
A/t
(c
m-1
)
The slope of the line gives as the constant k = 5206 cm-1. Thus the absorption equation gets the form A(c,t) = (5206c+0.42)t. Solve the equation for c and substitute the values:
1
1
0.610.42
0.4( , ) ( ) 0.000215206
Aa cm
t cmA c t kc a t ck cm
Thus the antioxidant content of the PE would be 0.021 mol-% with sample thickness 0.4 cm and UV absorbance 0.61.
• Do you know, how to define the slope and y-cross point of a line without spreadsheet program or graph calculator?
3. Crystallinity and IR
• Syndiotactic polystyrene (sPS) crystallizes in various crystal forms (, , , ) depending on crystallization conditions. The formation of -form is kinetically favorable whereas the formation of -form thermodynamically favorable.
• In the FTIR spectrum of syndiotactic polystyrene can be detected characteristic absorbance peaks; for amorphous (841 cm-1), - (851 cm-1) and -form (858 cm-1).
• Reminder:Atactic polystyrene is totally amorphous!
3. IR spectrum of syndiotactic PS
The characteristic infrared band of neat s-PS ranging from 940 to 820 cm−1:
a. quenched s-PS;
b. melt-crystallized s-PS at 240°C for 240 min;
c. sample in (b) heating scan up to 264°C from 30°C with 10°C/min, then quenched by liquid nitrogen.
3a)• Based on the measurement data calculate the averages for each
absorptivity ratio (a, a).• As an example, absorptivity ratio was calculated for the first sample:
• The other values are calculated in a similar manner and the average values
are calculated as well:
a = 0.179 and a = 0.270
1,8411,841
1,8511, AA
Aa
176.0706.0115.1
072.0
270.0608.0115.1
137.0
1,8411,841
1,8581,
AA
Aa
Sample A841* A841a A841b A851 A858 a a
1 1.115 0.706 0.608 0.072 0.137 0.176 0.2702 1.240 0.842 0.742 0.071 0.134 0.178 0.2693 0.916 0.642 0.544 0.050 0.101 0.182 0.272
mean 0.179 0.270
3b)• Taking into account that there is no b-form crystalline structure in a
sample of a-form and vice versa, the degree of crystallinity is calculated:
1,
1,8511,841
1,
1,851
1,
a
AA
a
A
X
432.0
179.0153.0
123.1
179.0153.0
266.0
270.0
043.0439.0
270.0
043.0
1,
1,8581,841
1,
1,858
1,
a
AA
a
A
X
aA
aA
A
aA
X858851
841
851
3b,c)
Sample t (min) A841 A851 X
1 2 1.123 0.153 0.4322 10 1.086 0.225 0.5373 240 0.311 0.077 0.580
Based on crystallinity degrees what can be said of the crystallization of syndiotactic PS?• Crystallinity increases with
extending isothermal crystallization period in both crystalline forms.
• The crystallinity of samples of -form is clearly bigger than the samples of -form. Therefore the crystallization rate of -form is faster.
• As it was already mentioned the formation of -form is kinetically favorable whereas the formation of -form thermodynamically favorable.
Sample t (min) A841 A858 X
1 2 0.439 0.043 0.2662 10 0.448 0.066 0.3533 240 0.377 0.068 0.400
Crystallinity of -form samples
Crystallinity of -form samples