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Title: Practicals report IB Chemistry
Description: In these notes you will find reports of 3 experiments done at the IB Diploma Programme Chemistry course (SL and HL): Determining the value of the gas constant, A traditional acid-alkali titration and Determining the amount of calcium carbonate in seashells (back titration). These notes are particularly helpful if you are struggling with the form of writing the report, if you have done any of these practicals in school and would like to check your lab results and report, or if you want to revise any of the folowing topics: stoichiometry, acids and bases (titration, back titration), gases (gas laws, ideal gases). It is also helpful to familiarize yourself with experimental reports before writing your IA (Internal Assessment).
Description: In these notes you will find reports of 3 experiments done at the IB Diploma Programme Chemistry course (SL and HL): Determining the value of the gas constant, A traditional acid-alkali titration and Determining the amount of calcium carbonate in seashells (back titration). These notes are particularly helpful if you are struggling with the form of writing the report, if you have done any of these practicals in school and would like to check your lab results and report, or if you want to revise any of the folowing topics: stoichiometry, acids and bases (titration, back titration), gases (gas laws, ideal gases). It is also helpful to familiarize yourself with experimental reports before writing your IA (Internal Assessment).
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Name Surname, class
date
CALCIUM CARBONATE (CaCO3) IN VARIOUS MARINE
ORGANISMS
INTRODUCTION
In this practical, we determined the percentage by mass of calcium carbonate (CaCO3) in a
seashell, a coral, a hermit crab and a sea urchin
...
A
known amount of excess acid was added to the sample to ensure that all the calcium
carbonate has reacted
...
Aliquotes of this deluded excess solution were then used for titration with a
standard solution of sodiun hydroxide
...
The
percentage in a shell and hermit crab is fairly similar
...
0001 g
Β± 0
...
05 cm3
50 cm3 conical flask
10 cm3 pipette
Β± 0
...
05 cm3
Name Surname, class
date
REACTIONS:
πΆππΆπ3 (π ) + 2π»πΆπ(ππ) β πΆππΆπ2 (π) + πΆπ2 (π) + π»2 π(π)
π»πΆπ(ππ) + ππππ»(ππ) β πππΆπ(ππ) + π»2 π(π)
PROCEDURE
1
...
The samples were
then grint into small pieces
...
About 0
...
Then, 20
...
00
mol/dm3 hydrochloric acid (HCl) was added into each flask
...
3
...
0 cm3 of distilled water was added to each flask and the contents
of these flasks were then transfered to a 100 cm3 volumetric flask where the diluded
acid was made to be 100 cm3 using more distilled water
...
10
...
100 mol/dm3 sodium hydroxide (NaOH) using phenolphthalein as
an indicator
...
50 cm3 of NaOH was added to a burette and then added drop by drop to solution
aliquotes
...
3 runs
were made for each sample
...
6
...
Name Surname, class
date
DATA PRESENTATION AND CALCULATIONS
RAW DATA:
1 (exoskeleton
of sea urchin)
Run 1
Run 2
Run 3
Average
m (sea urchin) = 0
...
0001
0
...
05 ml)
Vf (Β±0
...
1 ml)
5
...
30
24
...
30
24
...
80
9
...
7
8
...
0
= 1
...
478415139 Γ 10β2 % =
0
...
0111111111 = 1
...
0
2 (seashell)
Vi (Β±0
...
00
Run 2
8
...
50
Average
π (π πππ βπππ) = 0
...
0001
πΏ(π) =
= 1
...
515840534 Γ
0
...
10
πΏ(ππ’π ππ ) =
= 0
...
21506683 %
8
...
05 ml)
8
...
50
24
...
1 ml)
8
...
3
8
...
23
10β2 %
3 (coral)
Vi (Β±0
...
05 ml)
Run 1
24
...
50
Run 2
33
...
20
Run 3
8
...
50
Average
m (coral) = 0
...
0001
πΏ(π) =
= 1
...
512859304 Γ 10β2 %
0
...
1
πΏ(ππ’π ππ ) =
= 0
...
14547537 %
8
...
1 ml)
8
...
7
8
...
73
4 (hermit crab
Vi (Β±0
...
50
Run 2
26
...
20
Average
m(hermit crab) = 0
...
0001
πΏ(π) =
= 1
...
542971764 Γ
0
...
1
πΏ(ππ’π ππ ) =
= 0
...
12359551 %
8
...
05 ml)
Vused (Β±0
...
30
35
...
20
8
...
9
9
...
9
10β2 %
Name Surname, class
date
DATA PROCESSING AND PRESENTATION:
π
M (CaCO3) = 100
...
0 cm3 aliquot:
π(ππππ») = π(π»πΆπ)ππ₯πππ π = π β π(ππππ») = 8
...
986666667 β 10β3 πππ
β(π(π»πΆπ)ππ₯πππ π 1 ) = π(π»πΆπ)ππ₯πππ π 1 β πΏ(ππ’π ππ ) = 9
...
0055066667 πππ
2
β(π(πΆππΆπ3 )) = β(π(π»πΆπ)) + β(π(π»πΆπ)ππ₯πππ π 1 ) = 1
...
8148466366 = ππ
...
229473149 %
π(πΆππΆπ3 )
π€=
2 SEASHELL
In 10
...
233333333 β 10β4 πππ
In 100 cm3:
π(π»πΆπ)ππ₯πππ π 1 = π(π»πΆπ)ππ₯πππ π β 10 = 8
...
000405023 β 10β4 πππ
1
π(πΆππΆπ3 ) = β (π(π»πΆπ) β π(π»πΆπ)ππ₯πππ π 1 ) = 0
...
500405023 β 10β4 πππ
π(πΆππΆπ3 ) β π(πΆππΆπ3 )
= 0
...
ππππππππ %
π
β(π(πΆππΆπ3 )
β(π€) = (
+ πΏ(π)) β π€ = 2
...
0 cm3 aliquot:
π(ππππ») = π(π»πΆπ)ππ₯πππ π = π β π(ππππ») = 8
...
733333333 β 10β3 πππ
β(π(π»πΆπ)ππ₯πππ π 1 ) = π(π»πΆπ)ππ₯πππ π 1 β πΏ(ππ’π ππ ) = 1
...
0056333334 πππ
2
β(π(πΆππΆπ3 ) = β(π(π»πΆπ)) + β(π(π»πΆπ)ππ₯πππ π 1 ) = 1
...
8530110968 = ππ
...
284814318 %
π(πΆππΆπ3 )
π€=
4 HERMIT CRAB SHELL
In 10
...
900000000 β 10β4 πππ
In 100 cm3:
π(π»πΆπ)ππ₯πππ π 1 = π(π»πΆπ)ππ₯πππ π β 10 = 8
...
000000004 β 10β4 πππ
1
π(πΆππΆπ3 ) = β (π(π»πΆπ) β π(π»πΆπ)ππ₯πππ π 1 ) = 0
...
500000004 β 10β4 πππ
π(πΆππΆπ3 ) β π(πΆππΆπ3 )
π€=
= 0
...
ππππππππ %
π
β(π(πΆππΆπ3 )
β(π€) = (
+ πΏ(π)) β π€ = 2
...
So our hypothesis was not correct, since
we predicted the largest amount of CaCO3 in the coral
...
05 ml)
0
...
10
18
...
05 ml)
9
...
20
27
...
1 ml)
9
...
1
9
...
1
m(Na2CO3*xH2O) = 1
...
0001 g
Relative uncertainties:
0
...
246417013 β 10β5
1
...
1
πΏ(ππ’π ππ ) =
= 0
...
1
DATA PROCESSING AND PRESENTATION:
Equation of the reaction:
Na2CO3 (aq) + 2 HCl (aq)
2 NaCl (aq) + H2O (l) + CO2 (g)
In 25
...
1 β 10β10 πππ
π(π»πΆπ)
π1 (Na2CO3) =
= 4
...
55 β 10β3 πππ
β(π) = π(Na2CO3) β πΏ(ππ’π ππ ) = 0
...
55 β 10β3 πππ = 5
...
55 Β± 0
...
4823455 π
0
...
4823455 β
= 0
...
55
π(Na2CO3) = (0
...
005) π
Percentage yield:
ππ₯ππππππππ‘ππ π¦ππππ
%π¦ππππ =
= 0
...
Name Surname, class
date
To find out the x in Na2CO3*xH2O:
π(Na2CO3*xH2O)
1
...
6923077
π(Na2CO3*xH2O) 4
...
6923077 β (0
...
246417013 β 10β5 ) = 2
...
6923077 β 106
...
6923077
π₯=
M(xH2O) 131
...
308119184
M(H2O)
18
...
1
2
π₯ = 7
...
1
Formula of the reactant:
Na2CO3*7H2O
3
2
π
πππ
Name Surname, class
date
DETERMINING THE VALUE OF THE GAS CONSTANT
MATERIALS AND TOOLS:
magnesium ribbon, copper wire, 20 % HCl, 50-Ml, burette, bung with a hole, beakers, thermometer,
barometer, funnel, 250 cm3 cylinder, plastic tray, tap water, distilled water, top pan balance,
analytical balance and sandpaper
PROCEDURE:
β’
β’
β’
β’
β’
β’
β’
First an appropriate amount of magnesium ribbon was obtained
...
A 5 cm
long piece of magnesium ribbon was weighted and hence the length of a 0
...
The assumption that the magnesium ribbon is
homogenous was made at this point
...
Then the volume of burette between the bottom graduation and the tap (the βdead
volumeβ) was measured
...
Using Pasteur pipette the water was filled exactly to the bottom
graduation
...
The volume of water was then calculated from its mass
...
20 % hydrochloric acid was added to near the 40 cm3 mark
...
Acid remained at the bottom as a separate layer
...
The hole in the bung was closed with a finger before the burette was inverted
...
After some time when there was no further reaction (when all the magnesium had dissolved)
the burette was placed in the measuring cylinder so that water levels inside the burette and
the measuring cylinder were the same
...
Room temperature and pressure were measured
...
0472 Β± 0
...
1 Β± 0
...
2 Β± 0
...
8 Β± 0
...
0021186441
0
...
0010288066
0
...
0199349800
Name Surname, class
date
Total relative uncertainty = 0
...
0047393365 + 0
...
0120481928 =
= 0
...
2β0
...
305
=
294
...
0472
8
...
0199349800 * 8
...
1689545976 Jβ Kβ1β molβ1
R = 8
...
2 Jβ Kβ1β molβ1
Taking into consideration the vapour pressure of water:
Not all the pressure inside the burette was a consequence of H2, because there was probably some
water vapour
...
3 kPa
...
(πβ2
...
2β2
...
0498β24
...
3β0
...
269112869 Jβ Kβ1β molβ1
Absolute uncertainty = 0
...
269112869 = 0
...
3 Β± 0
...
CONCLUSION AND EVALUATION:
The final result was quite accurate and precise, specially after taking into consideration the vapour
pressure of water
...
3 Β± 0
...
31 Jβ Kβ1β molβ1
...
Name Surname, class
date
This model assumes that the gas is an ideal gas, which means that there are no interactions between
the particles and that the particles do not occupy any space
...
Most heavy gases, like many refrigerants and gases with strong intermolecular forces, like
water vapor also donΒ΄t obey the model of ideal gas law
...
Also avoiding the copper spiral would make it
more accurate as some copper still reacted with HCl and produced some gas (H2)
...
Title: Practicals report IB Chemistry
Description: In these notes you will find reports of 3 experiments done at the IB Diploma Programme Chemistry course (SL and HL): Determining the value of the gas constant, A traditional acid-alkali titration and Determining the amount of calcium carbonate in seashells (back titration). These notes are particularly helpful if you are struggling with the form of writing the report, if you have done any of these practicals in school and would like to check your lab results and report, or if you want to revise any of the folowing topics: stoichiometry, acids and bases (titration, back titration), gases (gas laws, ideal gases). It is also helpful to familiarize yourself with experimental reports before writing your IA (Internal Assessment).
Description: In these notes you will find reports of 3 experiments done at the IB Diploma Programme Chemistry course (SL and HL): Determining the value of the gas constant, A traditional acid-alkali titration and Determining the amount of calcium carbonate in seashells (back titration). These notes are particularly helpful if you are struggling with the form of writing the report, if you have done any of these practicals in school and would like to check your lab results and report, or if you want to revise any of the folowing topics: stoichiometry, acids and bases (titration, back titration), gases (gas laws, ideal gases). It is also helpful to familiarize yourself with experimental reports before writing your IA (Internal Assessment).