Time, temperature, mass & volume
Time
Time can be measured using a stopwatch or stopclock which are usually accurate to one or two decimal places
The units of time normally used are seconds or minutes
Other units may be used for extremely slow reactions (e.g. rusting)
Remember: 1 minute = 60 seconds
Examiner Tips and Tricks
Careful: Units of time often cause issues in results tables.
If the display on a stopwatch showed 1:30.
The incorrect time to record would be 1.30 minutes.
The correct time would be 1.5 minutes.
To avoid any confusion, if the time intervals are less than a minute, it is best / easire to change the recorded units to seconds.
So, the same stopwatch display would be recorded as 90 seconds.
Temperature
Temperature is measured with a thermometer or digital temperature probe
Laboratory thermometers usually have a precision of a half or one degree
Digital temperature probes are available which are more precise than traditional thermometers and can often read to 0.1 oC
Traditional thermometers rely upon the uniform expansion and contraction of a liquid substance with temperature
Digital temperature probes can be just as, if not, more accurate than traditional thermometers
The units of temperature are degrees Celsius (ºC)
Mass
Mass is measured using a digital balance which normally gives readings to two decimal places
Balances should be tared (set to zero) before use
Balances should also be allowed time to settle on a final measurement / reading before it is recorded
The standard unit of mass in kilograms (kg)
However, in chemistry grams (g) are most often used
Remember: 1 kilogram = 1000 grams
Volumes of liquid
The volume of a liquid can be determined using different pieces of apparatus
The choice of apparatus depends on the level of accuracy needed
Three common pieces of apparatus for measuring the volume of a liquid are:
Burettes
Volumetric pipettes
Measuring cylinders
Burettes are the most accurate way of measuring a variable volume of liquid between 0 cm3 and 50 cm3
They are most commonly used in titrations
Careful: Read the burette scale from top to bottom as 0.00 cm3 is at the top of the column
Volumetric pipettes are the most accurate way of measuring a fixed volume of liquid,
They have a scratch mark on the neck which is matched to the bottom of the meniscus to make the measurement
A pipette filler is used to draw the liquid into the volumetric pipette
The most common volumes for volumetric pipettes are 10 cm3 and 25 cm3
Measuring cylinders are used when approximate volumes are required (accuracy is not an important factor)
These are graduated (have a scale so can be used to measure)
Measuring cylinders typically range from 10 cm3 to 1 litre (1 dm3)
Whichever apparatus you use, you may see markings in millilitres, ml, which are the same as a cm3
Volumes of gas
For some experiments, the volume of a gas produced needs to be measured
This is typically done by using one of the following methods:
Using a gas syringe
By downward displacement of water
A gas syringe is more precise and accurate than downward displacement of water
Diagram of the set-up for an experiment involving a gas syringe
Downward displacement of water is where a measuring cylinder is inverted in water to collect the gas produced
This method does not work if the gas is soluble in water
Diagram of the set-up for an experiment collecting gas by downward displacement of water
If the gas happens to be heavier than air and is coloured, the cylinder does not need to be inverted
Advantages & disadvantages of methods & apparatus
In the lab, we often have choices of different apparatus to do the same job
Evaluating which piece of apparatus is the best one to use is part of good experimental planning and design
This means appreciating some of the advantages and disadvantages of laboratory apparatus
Advantages and disadvantages of lab apparatus
Apparatus | Advantage | Disadvantage |
Temperature probe |
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Volumetric pipette |
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Gas syringe |
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Microscale experiments |
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Five pieces of apparatus that can be used to measure the volume of a liquid. They all have their pros and cons
Planning your method
Good experimental design includes the answers to questions like
Have I chosen a suitable apparatus for what I need to measure?
Is it going to give me results in an appropriate time frame?
Is it going to give me enough results to process, analyse and make conclusions?
Does it allow for repetitions to check how reliable my results are?
Does my plan give a suitable range of results?
How can I be sure my results are accurate?
Have I chosen an appropriate scale of quantities without being wasteful or unsafe?
You may be asked about experimental methods in exam questions and your experience and knowledge of practical techniques in chemistry should help you to spot mistakes and suggest improvements
Solutions
You need to know all the following terms used when describing solutions:
Terminology about solutions table
Term | Meaning | Example |
Solvent | The liquid in which a solute dissolves | The water in seawater |
Solute | The substance which dissolves in a liquid to form a solution | The salt in seawater |
Solution | The mixture formed when a solute is dissolved in a solvent | Seawater |
Saturated solution | A solution with the maximum concentration of solute dissolved in the solvent | Seawater in the Dead Sea |
Soluble | A substance that will dissolve | Salt is soluble in water |
Insoluble | A substance that will not dissolve | Sand is insoluble in water |
Filtrate | The liquid or solution that has passed through a filter | Fresh coffee in a cup |
Residue | The substance that remains after evaporation, distillation, filtration or any other similar process | Coffee grounds in filter paper |
Acid-base titrations
Titrations are a method of analysing the concentration of solutions
They can determine exactly how much alkali is needed to neutralise a quantity of acid – and vice versa
You may be asked to perform titration calculations to determine the moles present in a given amount or the concentration / volume required to neutralise an acid or a base
Titrations can also be used to prepare salts
Apparatus
25 cm3 volumetric pipette
Pipette filler
50 cm3 burette
250 cm3 conical flask
Small funnel
0.1 mol / dm3 sodium hydroxide solution
Sulfuric acid of unknown concentration
A suitable indicator
Clamp stand, clamp & white tile
The steps in performing a titration
Method
Use the pipette and pipette filler and place exactly 25 cm3 sodium hydroxide solution into the conical flask
Using the funnel, fill the burette with hydrochloric acid placing an empty beaker underneath the tap. Run a small portion of acid through the burette to remove any air bubbles
Record the starting point on the burette to the nearest 0.05 cm3
Place the conical flask on a white tile so the tip of the burette is inside the flask
Add a few drops of a suitable indicator to the solution in the conical flask
Perform a rough titration by taking the burette reading and running in the solution in 1 – 3 cm3 portions, while swirling the flask vigorously
Quickly close the tap when the end-point is reached
The endpoint is when one drop causes a sharp colour change
Record the volume of hydrochloric acid added, in a suitable results table as shown below
Make sure your eye is level with the meniscus
Repeat the titration with a fresh batch of sodium hydroxide
As the rough end-point volume is approached, add the solution from the burette one drop at a time until the indicator just changes colour
Record the volume to the nearest 0.05 cm3
Repeat until you achieve two concordant results (two results that are within 0.1 cm3 of each other) to increase accuracy
| Rough titre | Titre 1 | Titre 2 | Titre 3 |
Final reading (cm3) |
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First reading (cm3) |
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Titre (cm3) |
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Examiner Tips and Tricks
Common errors during a titration include:
Not removing the funnel from the burette
This can lead to some liquid dripping into the burette and cause false / high readings
Not filling the jet space of the burette
The jet space is the part of the burette after the tap
Not filling this space can lead to false readings
Reading the volume from the burette incorrectly
Readings should be taken from the bottom of the meniscus
Careful: The scale on the burette has 0.0 cm3 at the top and 50 cm3 (typically) at the bottom
Indicators
Indicators are used to show the endpoint in a titration
Wide range indicators such as litmus are not suitable for titration as they do not give a sharp colour change at the endpoint
However, methyl orange and phenolphthalein are very suitable
Some of the most common indicators with their corresponding colours are shown below:
Common acid-base indicators
Indicator | Colour in acid | Colour in alkali | Colour in neutral |
Litmus solution | Red | Blue | Purple |
Red litmus paper | Stays red | Turns blue | No change |
Blue litmus paper | Turns red | Stays blue | No change |
Methyl orange | Red | Yellow | Orange |
Phenolphthalein | Colourless | Pink | Colourless |
Thymolphthalein | Colourless | Blue | Colourless |
Paper chromatography
Chromatography is used to separate substances and provide information to help identify them
The components have different solubilities in a given solvent
E.g. Different coloured inks that have been mixed to make black ink
A pencil line is drawn on chromatography paper and spots of the sample are placed on it
A pencil is used for this as ink would run into the chromatogram along with the samples
The paper is then lowered into the solvent container, making sure that the pencil line sits above the level of the solvent so the samples don’t wash into the solvent container
The solvent used is usually water but it can be other substances such as ethanol
The solvent travels up the paper by capillary action, taking some of the coloured substances with it
Different substances have different solubilities so they will travel at different rates, causing the substances to spread apart
Those substances with higher solubility will travel further than the others
How to carry out chromatography
The pigments in ink can be analysed using paper chromatography
Interpret simple chromatograms
We can use a chromatogram to compare the substances present in a mixture to known substances and make assumptions
Pure substances will produce only one spot on the chromatogram
Impure substances will produce more than one spot on the chromatogram
If two or more substances are the same, they will produce identical chromatograms
If the substance is a mixture, it will separate on the paper to show all the different components as separate spots
It is common practice to include a known compound as a reference spot
This can help match up to an unknown spot or set of spots in order to identify it
Example chromatogram results
The brown ink has separated showing a spot of red ink, blue ink and yellow ink
We can draw several conclusions from this chromatogram:
The brown ink is a mixture as there are three dots
Red, yellow and blue are pure as there is only one dot for each
The brown ink contains red, blue and yellow as the dots are in line with one another horizontally
Examiner Tips and Tricks
Chromatograms in exams will be in black and white so to identify whether a mixture contains a known sample, the dots need to be in line with one another. Locating agents
Extended tier only
For chromatography to be useful, the chemist needs to be able to see the components move up the paper
This is not the case for colourless substances such as amino acids or sugars
Locating agents can be used to see the spots
These are substances which react with the sample and produce a visible / coloured spot for the product(s)
The chromatogram is treated with the agent after the chromatography run has been carried out, making the sample runs visible to the naked eye
Retention factor (Rf) values
Extended tier only
Rf values are used to identify the components of mixtures
The Rf value of a particular compound is always the same
However, it does depend on the solvent used
If the solvent is changed then the Rf value changes
Calculating the Rf value allows chemists to identify unknown substances because it can be compared with the Rf values of known substances under the same conditions
The retention factor, Rf, is calculated by the equation:
Rf =
The Rf value:
Is a ratio
Has no units
Will always be less than 1
Worked Example
A student obtained the following chromatogram when carrying out chromatography.
Calculate the Rf value of the substance.
Answer:
The Rf value of the substances in the chromatogram above can be calculated by:
Rf = = = 0.5
Examiner Tips and Tricks
When you calculate Rf values in exams, make sure to use your ruler carefully to measure the distance moved by the solvent and the substance as mark schemes can be strict about the values accepted for these.
Filtration & crystallisation
The choice of separation technique depends on the substances being separated
All techniques rely on a difference in properties of the chemicals in the mixture
This is usually a physical property such as boiling point
Separating a mixture of solids
Differences in solubility can be used to separate solids
For a difference in solubility, a suitable solvent must be carefully chosen
Only the desired substance should dissolve in the solvent
Other substances or impurities in the mixture should not dissolve in the solvent
For example, to separate a mixture of sand and salt:
Water is a suitable solvent because salt is soluble in water, but sand is insoluble in water
Filtration
This technique is used to separate an undissolved solid from a mixture of the solid and a liquid / solution ( e.g. sand from a mixture of sand and water)
Centrifugation can also be used for this mixture
A filter paper is placed in a filter funnel above another beaker
The mixture of insoluble solid and liquid is poured into the filter funnel
The filter paper will only allow small liquid particles to pass through in the filtrate
Solid particles are too large to pass through the filter paper so will stay behind as a residue
Filtration of a mixture of sand and water
Crystallisation
This method is used to separate a dissolved solid from a solution
A simple application of this is to heat a solution to boiling, remove the heat and leave the solvent to evaporate
A more common application of this is sometimes called crystallisation
This is when the solid is more soluble in hot solvent than in cold, e.g. copper sulphate from a solution of copper(II) sulphate
The solution is heated, allowing the solvent to evaporate and leaving a saturated solution behind
You can test if the solution is saturated by dipping a clean, dry, cold glass rod into the solution
If the solution is saturated, crystals will form on the glass rod when it is removed and allowed to cool
The saturated solution is allowed to cool slowly
Solids will come out of the solution as the solubility decreases
This will be seen as crystals growing
The crystals are collected by filtration
They are then washed with distilled water to remove any impurities
Finally, they are allowed to dry
Common places to dry crystals are between sheets of filter paper or in a drying oven
The process of crystallisation
The solution is slowly heated to remove around half of the liquid. The remaining liquid will evaporate slowly
Examiner Tips and Tricks
In exams, you need to be specific that no more than half of the solution is removed by direct heating or you may lose a mark.
Distillation: simple & fractional
Simple distillation
Distillation is used to separate a liquid and soluble solid from a solution (e.g. water from a solution of saltwater) or a pure liquid from a mixture of liquids
The solution is heated and pure water evaporates producing a vapour which rises through the neck of the round-bottomed flask
The vapour passes through the condenser, where it cools and condenses, turning into pure water which is collected in a beaker
After all the water is evaporated from the solution, only the solid solute will be left behind
Simple distillation apparatus
Diagram showing the distillation of a mixture of salt and water
Simple distillation can be used to separate the products of fermentation, such as alcohol and water
However, fractional distillation is a more effective separation technique, commonly used when the boiling points of the liquids are close and/or a higher degree of purity is required, such as crude oil
Fractional distillation
Used to separate two or more liquids that are miscible with one another (e.g. ethanol and water from a mixture of the two)
The solution is heated to the temperature of the substance with the lowest boiling point
This substance will rise and evaporate first
The vapours will pass through a condenser, where they cool and condense
The condensed liquid is then collected in a beaker
All of the substance is evaporated and collected, leaving behind the other component(s) of the mixture
For water and ethanol:
Ethanol has a boiling point of 78 ºC
Water has a boiling point of of 100 ºC
The mixture is heated until it reaches 78 ºC, at which point the ethanol distills out of the mixture and into the beaker
When the temperature starts to increase to 100 ºC heating should be stopped as the water and ethanol are now separated
Fractional distillation of a mixture of ethanol and water
An electric heater is safer to use when there are flammable liquids present
The separation of the components in petroleum is achieved by fractional distillation on an industrial scale
Fractional distillation of crude oil is not carried out in school laboratories due to the toxic nature of some of the components of the crude oil, but it can sometimes be simulated using a synthetic crude oil made specially for the demonstration
Worked Example
A student is given a mixture of calcium sulfate, magnesium chloride and water. The table below shows some information about calcium sulfate and magnesium chloride.
substance | solubility in water | state at room temperature |
calcium sulfate | insoluble | solid |
magnesium chloride | soluble | solid |
How does the student obtain magnesium chloride crystals from the mixture?
Crystallisation followed by distillation
Crystallisation followed by filtration
Distillation followed by crystallisation
Filtration followed by crystallisation
Answer
The correct answer is D because:
The difference in solubility in water means the first step is to make a solution
The magnesium chloride will dissolve, but the solid calcium sulfate will be left behind
The mixture is filtered to remove the calcium sulfate and then evaporated and crystallised to obtain magnesium chloride crystals
Examiner Tips and Tricks
You may be asked how to separate a mixture of gases:
One method involves cooling the gaseous mixture sufficiently to liquefy all of the gases, which are then separated by fractional distillation.
They can also be separated by diffusion, where the boiling points are very close or it is impractical or expensive to use fractional distillation.
Assessing purity
Pure substances melt and boil at specific and sharp temperatures
For example, water has a boiling point of 100°C and a melting point of 0°C
Mixtures have a range of melting and boiling points as they consist of different substances that melt or boil at different temperatures
Therefore, melting and boiling point data can be used to distinguish pure substances from mixtures
An unknown pure substance can be identified by experimentally determining its melting point and boiling point and comparing them to literature values / data tables
Boiling points are commonly determined by distillation
Melting point analysis is routinely used to assess the purity of drugs for example
This is done using a melting point apparatus which allows you to slowly heat up a small amount of the sample, making it easier to observe the exact melting point
Melting point test using an oil bath
This is then compared to data tables
The closer the measured value is to the actual melting or boiling point, the purer the sample is
If the sample contains impurities:
The boiling point may appear higher than the sample's actual boiling point
The melting point may appear lower than the sample's actual melting point
Identification of anions
Negatively charged non-metal ions are known as anions
You must be able to describe the tests for the following ions:
Carbonate ions, CO32–
Halide ions, Cl– , Br– , I–
Nitrate ions, NO3–
Sulfate ions, SO42–
Sulfite ions, SO32–
Test for carbonate ions
Carbonate compounds contain the carbonate ion, CO32-
The test for the carbonate ion is:
Add dilute acid
Bubble the gas released through limewater
Limewater turns cloudy if the carbonate ion is present
If a carbonate compound is present then fizzing / effervescence should be seen as CO2 gas is produced, which forms a white precipitate of calcium carbonate when bubbled through limewater:
CO32- (aq) + 2H+ (aq) → CO2 (g) + H2O (l)
CO2 (g) + Ca(OH)2 (aq) → CaCO3(s) + H2O(l)
The white precipitate turns limewater cloudy
Testing for carbonate ions
Limewater turns milky in the presence of carbon dixoide caused by the formation of insoluble calcium carbonate
Examiner Tips and Tricks
If you are asked to describe the test for carbonate ions, make sure that you say:
Bubble the gas produced through limewater, which turns cloudy if the carbonate ion is present
Just saying that limewater turns cloudy is not enough
This isn't describing the test, it is stating the result
Test for halide ions
Halide ions are the negative ions / anions formed by the elements in Group 7
The test for the halide ions is:
Acidify the sample with nitric acid
Add silver nitrate solution, AgNO3,
A silver halide precipitate forms if a halide ion is present
The precipitate is indicated by the state symbol (s)
The colour of the silver halide precipitate depends on the halide ion:
The chloride ion forms a white precipitate of silver chloride
potassium chloride + silver nitrate → potassium nitrate + silver chloride
KCl (aq) + AgNO3 (aq) → KNO3 (aq) + AgCl (s)
The bromide ion forms a cream precipitate of silver bromide
potassium bromide + silver nitrate → potassium nitrate + silver bromide
KBr (aq) + AgNO3 (aq) → KNO3 (aq) + AgBr (s)
The iodide ions forms a yellow precipitate of silver iodide
potassium iodide + silver nitrate → potassium nitrate + silver iodide
KI (aq) + AgNO3 (aq) → KNO3 (aq) + AgI (s)
Testing for halide ions
Each silver halide produces a precipitate of a different colour
Examiner Tips and Tricks
The acidification step in the halide ion test must be done with nitric acid rather than hydrochloric acid.
HCl contains the chloride ion which would interfere with the results.
Test for nitrate ions
Nitrate compounds contain the nitrate ion, NO3–
The test for the nitrate ion is
Add aqueous NaOH and aluminium foil
Warm gently and test the gas released
The gas given off is ammonia, NH3
Ammonia is a gas with a characteristic sharp choking smell that turns damp red litmus paper blue
Test for sulfate ions
Sulfate compounds contain the sulfate ion, SO42-
The test for the sulfate ion is:
Acidify the sample with dilute nitric acid
Add a few drops of barium nitrate solution
A white precipitate of barium sulfate is formed, if the sulfate ion is present
Ba2+ (aq) + SO42- (aq) → BaSO4 (s)
The test can also be carried out with barium nitrate solution
Testing for sulfate ions
A white precipitate of barium sulfate is a positive result for the presence of sulfate ions
Examiner Tips and Tricks
Nitric is added first to remove any carbonates which may be present which would also produce a precipitate and interfere with the results.
Test for sulfite ions
Sulfite compounds contain the sulfite ion, SO32-
The test for the sulfite ion is:
Add dilute acid
Warm the mixture gently
Bubble the gas released through potassium manganate(VII) solution
The potassium manganate(VII) solution changes from purple to colourless if the sulfite ion is present
Examiner Tips and Tricks
For qualitative inorganic analysis, there will be one test for the metal cation and another test for the non-metal anion.
If you are an extended level student you may be asked to write balanced ionic equations for cation and anions tests, so make sure you know the formulae of all the ions and precipitates formed.
Identification of cations
Test for ammonium ions
Ammonium ions, NH4+, can be identified by gently warming a solution containing the ions with sodium hydroxide solution
The sodium hydroxide solution is a source of hydroxide ions, OH–, for the test
This releases ammonia gas which turns damp red litmus paper blue
Testing for ammonium ions
Heating ammonium ions with sodium hydroxide solution releases ammonia gas which turns damp red litmus blue
Metal cations in aqueous solution can be identified by the colour of the precipitate they form on addition of sodium hydroxide and ammonia
Most transition metals produce hydroxides with distinctive colours
Test for metal ions with sodium hydroxide solution
If a small amount of sodium hydroxide solution is used, the resulting metal hydroxide normally precipitates out of solution
If excess sodium hydroxide solutionis used, some of the precipitates may re-dissolve
For this reason, just a few drops of sodium hydroxide solutionare added at first and very slowly
The sodium hydroxide test for the metal ion is:
Add a few drops of sodium hydroxide solution
Record any colour changes or precipitates formed
Add excess sodium hydroxide solution
Record any colour changes or changes to precipitates
Test for metal ions with ammonia solution
If a small amount of ammonia solution is used, the resulting metal hydroxide normally precipitates out of solution
If excess ammonia solution is used, some of the precipitates may re-dissolve
For this reason, just a few drops of ammonia solution are added at first and very slowly
The ammonia test for the metal ion is:
Add a few drops of ammonia solution
Record any colour changes or precipitates formed
Add excess ammonia solution
Record any colour changes or changes to precipitates
Metal ion tests summary
Initially, sodium hydroxide solution and ammonia solution give the same results for 2 - 3 drops
This is because they both contain the hydroxide ion, OH–
Metal Ion | Addition of 2-3 drops of NaOH or ammonia | Addition of excess NaOH | Addition of excess ammonia |
Al3+ | White precipitate forms | Precipitate dissolves to form a colourless solution | Precipitate does not dissolve |
Ca2+ | White precipitate forms | Precipitate does not dissolve | Precipitate does not dissolve |
Cr3+ | Green precipitate forms | Precipitate dissolves to form a green solution | Precipitate does not dissolve |
Cu2+ | Light blue precipitate forms | Precipitate does not dissolve | Precipitate dissolves to form a dark blue solution |
Fe2+ | Green precipitate forms | Precipitate does not dissolve | Precipitate does not dissolve |
Fe3+ | Brown precipitate forms | Precipitate does not dissolve | Precipitate does not dissolve |
Zn2+ | White precipitate forms | Precipitate dissolves to form a colourless solution | Precipitate dissolves to form a colourless solution |
Analysing results
The tables above contain the results for all metal cations included in the syllabus
If a precipitate is formed from either sodium hydroxide or ammonia solution, then the hydroxide is insoluble in water
For example, zinc chloride:
ZnCl2 (aq) + 2NaOH (aq) → Zn(OH)2 (s) + 2NaCl (aq)
There are 3 metal ions that all form white precipitates:
Aluminium ions, Al3+
Calcium ions, Ca2+
Zinc ions, Zn2+
Calcium ions, Ca2+, can be easily distinguished from Zn2+ and Al3+
The white precipitate of calcium hydroxide does not dissolve in excess sodium hydroxide solution
The white precipitates of zinc hydroxide and aluminium hydroxide dissolve in excess sodium hydroxide solution
Zinc ions, Zn2+, can then be distinguished from Al3+ ions as
The white precipitate of zinc hydroxide dissolves in excess ammonia solution
The white precipitate of aluminium hydroxide does not dissolve in excess ammonia solution
Examiner Tips and Tricks
The ammonia or sodium hydroxide solution must be added very slowly. If it is added too quickly and the precipitate is soluble in excess, then you run the risk of missing the formation of the initial precipitate, which dissolves as quickly as it forms if excess solution is added.
Be sure to distinguish between the term “colourless” and “clear”. A solution that loses its colour has become colourless. A clear solution is one that you can see through such as water. Solutions can be clear and have colour eg. dilute copper sulphate.
Flame tests for metal ions
The flame test is used to identify the metal cations by the colour of the flame they produce
Ions from different metals produce different colours
Dip the loop of an unreactive metal wire such as nichrome or platinum in concentrated acid and then hold it in the blue flame of a Bunsen burner until there is no colour change
This is an important step as the test will only work if there is just one type of ion present
Two or more ions means the colours will mix, making identification erroneous
This cleans the wire loop and avoids contamination
A small sample of the compound is placed on an unreactive metal wire loop such as nichrome or platinum
Dip the loop into the solid sample / solution and place it in the edge of the blue Bunsen flame
Avoid letting the wire get so hot that it glows red otherwise this can be confused with a flame colour
Diagram showing the technique for carrying out a flame test
The colour of the flame is observed and used to identify the metal ion present:
Cation | Flame Colour |
Li+ | Crimson |
Na+ | Yellow |
K+ | Lilac |
Ca2+ | Red |
Ba2+ | Apple-green |
Cu2+ | Blue-green |
Metal ions form distinctive coloured flames