IB Chemistry on Uncertainty calculation and significant figures

Significant figures

Used in measurements

Degree of precision

Show digits believed to be
correct/certain + 1 estimated/uncertain

All reads 80

80
80.0
80.00
80.000

Certain
23.00

least precise

Uncertain
5

Zeros bet
(significant)
4.109 = 4sf
902 = 3sf
5002.05 = 6sf

measurement
15.831g

23.005g
more precise

(15.831 ± 0.001)g
(5 sig figures)

Rules for significant figures

All non zero digit
(significant)
31.24 = 4 sf
563 = 3 sf
23 = 2sf

Number sf necessary to express a measurement
• Consistent with precision of measurement
• Precise equipment = Measurement more sf
• Last digit always an estimate/uncertain

Zeros after
decimal point
(significant)
4.580 = 4 sf
9.30 = 3sf
86.90000 = 7sf
3.040 = 4sf
67.030 = 5sf

Zero right of decimal point and
following a non zero digit
(significant)
0.00500 = 3sf
0.02450 = 4sf
0.04050 = 4sf
0.50 = 2sf

Deals with precision NOT accuracy!!!!!!!!
Precise measurement doesnt mean, it’s accurate
( instrument may not be accurate)

Zeros to left of digit
(NOT significant)
0.0023 = 2sf
0.000342 = 3sf
0.00003 = 1sf

Zero without decimal
(ambiguous)
80 = may have 1 or 2 sf
500 = may have 1 or 3 sf

Click here and here for notes on sig figures

Significant figures
1

22

Smallest division = 0.1

22

Max = 21.63
2

Certain
21.6

Uncertainty = 1/10 of smallest division.
= 1/10 of 0.1
= 1/10 x 0.1 = ±0.01

3

Certain = 21.6

4

Uncertain = 21.62 ±0.01

5

(21.62 ±0.01)

Measurement = Certain digits + 1 uncertain digit

Min = 21.61
Answer = 21.62 (4 sf)
21.6
(certain)

1

Smallest division = 1

2

= 1/10 of 1
= 1/10 x 1 = ±0.1

2
(uncertain)

Certain
36
3

Certain = 36

4


(36.5 ±0.1)

Uncertain = 36.5 ±0.1

5

Max = 36.6

Min = 36.4
Answer = 36.5 (3 sf)
36.
5
(certain) (uncertain)

Significant figures
1


Max = 47
2

Certain
40

= 1/10 of 10
= 1/10 x 10 = ±1

3

Certain = 40

4

Uncertain = 46 ±1

5

(46 ±1)


Min = 45
Answer = 46 (2 sf)
4
(certain)

1

Certain
3.4


2

= 1/10 of 0.1
= 1/10 x 0.1 = ±0.01

3

Certain = 3.4

4

Uncertain = 3.41±0.01

5


6
(uncertain)

Max = 3.42

(3.41 ±0.01)
Min = 3.40
Answer = 3.41 (3sf)
3.4
(certain)

1
(uncertain)

Significant figures
1


Max = 0.48

0.1
2

0.2
0.3

Certain
0.45

= 1/10 of 0.05
= 1/10 x 0.05 = ±0.005 (±0.01)
Certain = 0.45

Uncertain = 0.47 ± 0.01

5

0.5

3

4

0.4

(0.47 ±0.01)


Min = 0.46
Answer = 0.47 (2 sf)
0.4
(certain)

Measurement
1


2

= 1/10 of 0.1
= 1/10 x 0.1 = ±0.01

3

Certain = 5.7

4

Uncertain = 5.72 ± 0.01

(5.72 ±0.01)
Answer = 5.72 (3sf)
5.7
(certain)

2
(uncertain)

1


2

= 1/10 of 1
= 1/10 x 1 = ±0.1

3

Certain = 3

4

Uncertain = 3.0 ± 0.1

(3.0 ±0.1)
Answer =3.0 (2 sf)
3
0
(certain) (uncertain)

7
(uncertain)

Rules for sig figures addition /subtraction:
• Last digit retained is set by the first doubtful digit.
• Number decimal places be the same as least number of decimal places in any numbers being added/subtracted

23.112233
1.3324
+ 0.25
24.694633

uncertain
least number
decimal places

round down

4.7832
1.234
+ 2.02
8.0372

uncertain
least number
decimal places

round down

1247
134.5
450
+ 78
1909.5

uncertain

least number
decimal places

1.0236
- 0.97268
0.05092

4.2
2.32
+ 0.6157
7.1357

8.04
least number
decimal places
uncertain

round down

round up

0.03

uncertain
least number
decimal places

68.7
- 68.42
0.28

0.0509
least number
decimal places
uncertain

7.987
- 0.54
7.447

uncertain
least number
decimal places

round up

round down

round up

0.3

16.96

7.1
1.367
- 1.34
0.027

1910

12.587
4.25
+ 0.12
16.957

uncertain

round down

round up

24.69

least number
decimal places

uncertain
least number
decimal places

2.300 x 103
+ 4.59 x 103
6.890 x 103

least number
decimal places

7.45
Convert to same exponent
x 104
476.8

47.68
+ 23.2 x 103

x 103
+ 23.2 x 103
500.0 x 103

round up

6.89 x 103

500.0 x 103
5.000 x 105

least number
decimal places

Rules for sig figures - multiplication/division
• Answer contains no more significant figures than the least accurately known number.

12.34
3.22
x 1.8
71.52264

least sf (2sf)

round up

23.123123
x
1.3344
30.855495

least sf (5sf)

21.45
x 0.023
0.49335

round down

round down

30.855

72
16.235
0.217
x
5
17.614975

least sf (1sf)

round up

4.52
÷ 6.3578
7.1093775

least sf (3sf)

923
÷ 20312
0.045441

least sf (3sf)

round down

0.0454

1300
x 57240
74412000

4.6

0.00435
x
4.6
0.02001

least sf (2sf)

round down

7.11

0.020
least sf (2sf)
Scientific notation

least sf (2sf)

round up

0.49

round up

20

2.8723
x
I.6
4.59568

least sf (2sf)

6305
÷ 0.010
630500

least sf (2sf)

round down

63000

6.3 x 105

I.3*103
x 5.724*104
7.4412 x 107

round down

74000000

7.4 x 107

Click here for practice notes on sig figures

Scientific notation
How many significant figures

Written as
a=1-9

Number too big/small

b = integer

3 sf

Scientific  notation  a 10b

6,720,000,000

 6.72109

Size sand

4 sf

0.0000000001254

 1.2541010
3 sf

Speed of light

 3.00108

300000000

Scientific notation

80
80

How many significant figures

4.66 x
4660000

10 6

3 sf

4.660 x 10 6

5 sf

80.
80. – 8.0 x 101 – (2sf)
Digit 8 is certain
It can be 79 to 81

80.0
80.0 – 8.00 x 101 – (3sf)
Digit 80 is certain
It can be 79.9 or 80.1

4 sf

4.6600 x 10 6

80 – 8 x 101 – (1sf)
Digit 8 uncertain
It can be 70 to 90

3 ways to write 80

90 or 9 x 101
80 or 8 x 101
70 or 7 x 101

81 or 8.1 x 101
80 or 8.0 x 101
79 or 7.9 x 101

80.1 or 8.01 x 101
80.0 or 8.00 x 101
79.9 or 7.99 x 101
More precise

Click here practice scientific notation

Click here practice scientific notation

✔

Significant figures and Uncertainty in measurement
Recording measurement
using significant figures

Radius, r = 2.15 cm

Volume, V = 4/3πr3
V = 4/3 x π x (2.15)3
= 4/3 x 3.14 x 2.15 x 2.15 x 2.15
= 41.60

4/3 – constant
π – constant
Their sf is not taken
(not a measurement)
least sf (3sf)

round down

41.6
Recording measurement using
uncertainty of equipment

Radius, r = (2.15 ±0.02) cm

Treatment of Uncertainty
Multiplying or dividing measured quantities Volume, V = 4/3πr3
% uncertainty = sum of % uncertainty of individual quantities
Radius, r = (2.15 ±0.02)
%uncertainty radius (%Δr) = 0.02 x 100 = 0.93%
2.15
% uncertainty V = 3 x % uncertainty r
% ΔV = 3 x % Δr
* For measurement raised to power of n, multiply % uncertainty by n

* Constant, pure/counting number has no uncertainty and sf not taken

Volume, V = 4/3πr3

4
Volume   3.14  2.153  41.60
3
0.02
100%  0.93%
2.15
Measurement raised to power of 3,
multiply % uncertainty by 3
%V  3  %r
%V  3  0.93  2.79%
Volume  (41.60  2.79%)
%r 

AbsoluteV 

2.79
 41.60  1.16
100

Volume  (41.60  1.16)
Volume  (42  1)


Radius, r = 3.0 cm

Circumference, C = 2πr
C = 2 x π x (3.0)
= 2 x 3.14 x 3.0
= 18.8495

2 – constant
π – constant
(not a measurement)
least sf (2sf)

round up

19

Radius, r = (3.0 ±0.2) cm

Multiplying or dividing measured quantities Circumference, C = 2πr
Radius, r = (3.0 ±0.2)
%uncertainty radius (%Δr) = 0.2 x 100 = 6.67%
3.0
% uncertainty C = % uncertainty r
% ΔC = % Δr
* Constant, pure/counting number has no uncertainty and sf not taken

Circumference, C = 2πr

Circumference  2  3.14 3.0  18.8495

0.2
100%  6.67%
3.0
%c  %r
%c  6.67%
Circumference  (18.8495  6.67%)
%r 

AbsoluteC 

6.67
18.8495  1.25
100

Circumference  (18.8495  1.25)
Circumference  (19  1)


Time, t = 2.25 s

Displacement, s = ½ gt2
s = 1/2 x 9.8 x (2.25)2
= 24.80625

g and ½ – constant
(not a measurement)

least sf (3sf)

round down

24.8

Time, t = (2.25 ±0.01) cm

1
Displacement, s = gt 2
2
1
Displacement, s   9.8x2.25x2.25  24.80625
2

0.01
100%  0.4%
2.25
Measurement raised to power of 2,
multiply % uncertainty by 2
%s  2  %t
%s  2  0.4%  0.8%
Displacement  (24.80  0.8%)
%t 

1 2
Multiplying or dividing measured quantities Displacement, s = gt

2

Time, t = (2.25 ±0.01)
%uncertainty time (%Δt) = 0.01 x 100 = 0.4%
2.25
% uncertainty s = 2 x % uncertainty t
% Δs = 2 x % Δt

Absolutes 

0.4
 24.80  0.198
100

Displacement  (24.80  0.198)
Displacement  (24.8  0.2)


Length, I = 1.25 m

L
g

T  2

least sf (3sf)

T = 2 x π x √(1.25/9.8)
= 2 x 3.14 x 0.35714
= 2.24399

2, π and g – constant
(not a measurement)

round down

2.24

T  2

Length, I = (1.25 ±0.05) m

T  2

L
g
1.25
 2.24
9. 8

0.05
100%  4%
1.25
1
Measurement raised to power of 1/2,
%T   %l multiply % uncertainty by 1/2
2
%T  2%
%l 

Multiplying or dividing measured quantities

T  2

L
g

Length, I = (1.25 ±0.05)
%uncertainty length (%ΔI) = 0.05 x 100 = 4%
1.25
% uncertainty T = ½ x % uncertainty I
% ΔT = ½ x % ΔI

T  (2.24  2%)
AbsoluteT 

2
 2.24  0.044
100

T  (2.24  0.044)
T  (2.24  0.04)


Area, A = I x h

Length, I = 4.52 cm
Height, h = 2.0 cm

4.52
2.0
9.04

x

least sf (2sf)

round down

9.0

Length, I = (4.52 ±0.02) cm
Height, h = (2.0 ±0.2)cm3

Area, A = I x h

Area  4.52 2.0  9.04

0.02
100%  0.442%
4.52
0.2
%h 
100%  10%
2.0
%A  %l  %h
%l 


Area, A  Length, l  height, h

Length, l = (4.52 ±0.02)
%uncertainty length (%Δl) = 0.02 x 100 = 0.442%
4.52
Height, h = (2.0 ±0.2)
%uncertainty height (%Δh) = 0.2 x 100 = 10%
2.0
% uncertainty A = % uncertainty length + % uncertainty height
% ΔA =
% ΔI
+
%Δh

%A  0.442%  10%  10.442%
Area  (9.04  10.442%)
AbsoluteA 

Area  (9.0  0.9)

10.442
 9.04  0.9
100


Moles, n = Conc x Vol

Conc, c
= 2.00 M
Volume, v = 2.0 dm3

2.00
2.0
4.00

x

least sf (2sf)

round down

4.0

Conc, c
= (2.00 ±0.02) M
Volume, v = (2.0 ±0.1)dm3

Mole, n  Conc, c Volume, v

Mole  2.00 2.0  4.00
0.02
100%  1%
2.00
0.1
%v 
100%  5%
2.0
%n  %c  %v
%c 


Mole, n  Conc, c Vol, v

Conc, c = (2.00 ±0.02)
%uncertainty conc (%Δc) = 0.02 x 100 = 1%
2.00
Volume, v = (2.0 ±0.1)
%uncertainty volume (%Δv) = 0.1 x 100 = 5%
2.0
% uncertainty n = % uncertainty conc + % uncertainty volume
% Δn =
% Δc
+
%Δv

%n  1%  5%  6%
Mole  (4.00  6%)
Absoluten 

6
 4.00  0.24
100

Mole  (4.00  0.24)
Mole  (4.0  0.2)


Mass, m = 482.63g
Volume, v = 258 cm3

Density = Mass
Volume
482.63
÷
258
1.870658

least sf (3sf)

round down

1.87

Mass, m = (482.63 ±1)g
Volume, v = (258 ±5)cm3


Density, D =

Mass
Volume

Mass, m = (482.63 ±1)
%uncertainty mass (%Δm) = 1
x 100 = 0.21%
482.63
Volume, V = (258 ±5)
%uncertainty vol (%ΔV) = 5 x 100 = 1.93%
258
% uncertainty density = % uncertainty mass + % uncertainty volume
% ΔD =
% Δm
+
%ΔV

Density, D =
Density, D =

Mass
Volume

482.63
=1.870658
258

1
100%  0.21%
482.63
5
%V 
100%  1.93%
258
%D  %m  %V
%m 

%D  0.21%  1.93%  2.14%
Density  (1.87  2.14%)
AbsoluteD 

2.14
1.87  0.04
100

Density  (1.87  0.04)


Mass water = 2.00 g
ΔTemp
= 2.0 C

Enthalpy, H = mcΔT

x

2.00
4.18
2.0
16.72

c – constant
sf is not taken
(not a measurement)

least sf (2sf)

round up

17


Mass water = (2.00 ±0.02)g
ΔTemp
= (2.0 ±0.4) C


Enthalpy, H  m  c  T
Enthalpy, H  2.00 4.18 2.0  16.72


Mass, m = (2.00 ±0.02)
%uncertainty mass (%Δm) = 0.02 x 100 = 1%
2.00
ΔTemp = (2.0 ±0.4)
%uncertainty temp (%ΔT) = 0.4 x 100 = 20%
2.0
% uncertainty H = % uncertainty mass + % uncertainty temp
% ΔH =
% Δm
+
%ΔT

0.02
100%  1%
2.00
0.4
%T 
100%  20%
2.0
%H  %m  %T
%m 

%H  1%  20%  21%
Enthalpy  (16.72  21%)
AbsoluteH 

21
16.72  3.51
100

Enthalpy  (16.72  3.51)
Enthalpy  (17  4)

Treatment of uncertainty in measurement

•

Adding or subtracting
Max absolute uncertainty is the SUM of individual uncertainties

Initial mass beaker, M1
= (20.00 ±0.01) g
Final mass beaker + water, M2 = (22.00 ±0.01)g

Addition/Subtraction/Multiply/Divide

•

Multiplying or dividing
Max %uncertainty is the SUM of individual %uncertainties
Addition/Subtraction
Add absolute uncertainty

Initial Temp, T1 = (21.2 ±0.2)C
Final Temp, T2 = (23.2 ±0.2)C

Enthalpy, H = (M2-M1) x c x (T2-T1)
Mass water, m = (M2 –M1)
Absolute uncertainty, Δm = (0.01 + 0.01) = 0.02

Diff Temp ΔT = (T2 –T1)
Absolute uncertainty, ΔT = (0.2 + 0.2) = 0.4
Multiplication
Add % uncertainty

Mass water, m = (22.00 –20.00) = 2.00
Absolute uncertainty, Δm = (0.01 + 0.01) = 0.02
Mass water, m = (2.00 ±0.02)g

Mass water, m = (2.00 ±0.02)g


Diff Temp ΔT = (23.2 –21.2) = 2.0
Absolute uncertainty, ΔT = (0.2 + 0.2) = 0.4
Diff Temp, ΔT = (2.0 ±0.4)
ΔTemp = (2.0 ±0.4) C


Mass, m = (2.00 ±0.02)
%uncertainty mass (%Δm) = 0.02 x 100 = 1%
2.00
ΔTemp = (2.0 ±0.4)
%uncertainty temp (%ΔT) = 0.4 x 100 = 20%
2.0
% uncertainty H = % uncertainty mass + % uncertainty temp
% ΔH =
% Δm
+
%ΔT


Enthalpy, H  2.00 4.18 2.0  16.72
0.02
100%  1%
2.00
0.4
%T 
100%  20%
2.0
%H  %m  %T
%m 

%H  1%  20%  21%
Enthalpy  (16.72  21%)
AbsoluteH 

21
16.72  3.51
100

Enthalpy  (16.72  3.51)
Enthalpy  (17  4)


tI2
Energy  1/ 2
v
4.52 x 3.0 x 3.0 = 40.68
÷ 1.414
28.769

Volt, v = 2.0 V
Current, I = 3.0A
Time, t = 4.52s

least sf (2sf)

round up

29
Volt, v = (2.0 ± 0.2)
Current, I = ( 3.0 ± 0.6)
Time, t = (4.52 ± 0.02)


tI2
Energy, E  1/ 2
v

Time, t = (4.52 ±0.02)
%uncertainty time (%Δt) = 0.02 x 100 = 0.442%
4.52
Current, I = (3.0 ±0.6)
%uncertainty current (%ΔI) = 0.6 x 100 = 20%
3.0
Volt, v = (2.0±0.2)
%uncertainty volt (%Δv) = 0.2 x 100 = 10%
2.0
% ΔE = % Δt + 2 %ΔI + ½ %ΔV

tI2
Energy, E  1/ 2
v
4.52(3.0) 2
Energy, E 
 28.638
2.01/ 2
0.02
% t 
 100%  0.442%
4.52
0 .6
% I 
 100%  20%
3 .0
0.2
% v 
 100%  10%
2.0

1
%E  %t  2  % I   %v
2
%E  

0.02
0.6
1 0.2
100%    2  100%     100%
4.52
3.0
2 2.0

%E  0.442%  40%  5%  45.442%  45%

Energy, E  (28.638  45%)
AbsoluteE 

Energy, E  (29  13)

45
 28.638  13
100




(G + H )
Z
20 + 16 = 36
÷ 106
0.339

Speed, s =

G = (20 )
H = (16 )
Z = (106)

least sf (2sf)

round down

0.34

Speed, s 

G = (20 ± 0.5)
H = (16 ± 0.5)
Z = (106 ± 1.0)

✔

Addition
add absolute uncertainty

G+H = (36 ± 1)
Z = (106 ± 1.0)

(G  H )
Z

Speed, s 

(20  16)
 0.339
106

%(G  H ) 

(G + H )
Speed, s =
Z

(G + H) = (36 ±1)
%uncertainty (G+H) (%ΔG+H) = 1 x 100 = 2.77%
36
Z = (106 ±1.0)
%uncertainty Z (%Δz) = 1.0 x 100 = 0.94%
106
%uncertainty s = %uncertainty(G+H) + %uncertainty(Z)
% Δs = % Δ(G+H)
+
%Δz
*Adding or subtracting
Max absolute uncertainty is the SUM of individual uncertainties

%Z 

1.0
100%  2.77%
36

1.0
100%  0.94%
106

%S  %(G  H )  %Z
%S  2.77%  0.94%  3.71%

Speed, s  (0.339  3.71%)
AbsoluteS 

3.71
 0.339  0.012
100

Speed, s  (0.339  0.012)
Speed, s  (0.34  0.01)

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