Reactions of metals with oxygen

Chapter overview

1.5 weeks

In this chapter learners will again encounter the reactions of selected metals with oxygen that were used as examples in the previous chapter. In this chapter, however, there will be a greater focus on the actual reactions - these should be demonstrated to the class - and the commonalities between them. Once again, the writing of chemical equations will be scaffolded by the process of starting with a word equation (macroscopic representation) and progressing through a picture equation (submicroscopic representation) to end at the chemical equation (symbolic representation).

The content has also been presented in a slightly different order to CAPS in that the example reactions are first explored, and then the general reaction of metals with oxygen is explained, once learners have already seen example chemical equations.

3.1 The reaction of iron with oxygen (1 hour)

Tasks

Skills

Recommendation

Activity: Three different levels of interpretation in science

Sorting and classifying, interpreting, identifying

Optional (Revision)

Activity: The reaction of iron with oxygen

Demonstration of steel wool burning, observing, recording, communicating, describing

CAPS suggested

3.2 The reaction with magnesium and oxygen (1 hour)

Tasks

Skills

Recommendation

Activity: The reaction of magnesium with oxygen

Demonstration of magnesium burning, observing, recording, communicating, describing

CAPS suggested

3.3 The general reaction of metals with oxygen (0.5 hours)

(Questions within the text)

3.4 The formation of rust (1.5 hour)

Tasks

Skills

Recommendation

Activity: The reaction between iron and oxygen in air

Demonstrating, observing, recording, describing,

Optional (Suggested)

Activity: Why is rust a problem?

Identifying problems and issues

Optional (Suggested)

3.5 Ways to prevent rust (0.5 hours)

(Questions within the text)

  • What happens when a metal reacts with oxygen?
  • What is the product called?
  • How can we represent the general reaction between a metal and oxygen?
  • What is a combustion reaction?
  • What is rust and how does it form?
  • How can iron be made more rust-resistant?

In the previous chapter, we learnt how to write and balance equations. The three examples we learnt about were:

  • magnesium + oxygen → magnesium oxide

  • iron + oxygen → iron oxide

  • copper + oxygen → copper oxide

Which groups do magnesium, iron and copper come from?



Magnesium is group 2, iron is group 8 and copper is group 11. This is important as elements in the same group will react similarly.

In these reactions, the elements that react with oxygen are all metals. If you are not convinced of this, find them on the Periodic Table below in the front of your book. Can you see that they are all found in the region occupied by the metals? Where are metals located on the Periodic Table?


On the left.

The names of the products of the three reactions above have something in common. Write down the names. Can you see what they have in common?



The products are: magnesium oxide, iron oxide, copper oxide. They all have 'oxide' in their name.

The products are all metal oxides. What exactly are metal oxides? As we will see later when we draw diagrams and write formulae to represent these reactions, they are compounds in which a metal is combined with oxygen, in some fixed ratio.

The metals will react similarly with the other elements in the same group as oxygen (group 16).

We are going to look at two of the reactions shown previously in greater detail in this chapter. Remember that they are not the only reactions of metals with oxygen; they are just the ones that have been chosen as examples.

First, we will observe the actual reactions. Your teacher will demonstrate, while you make observations. Afterwards we will write about these reactions using 'scientific language' as we write reaction equations for each one. Before we start, here is a reminder of something we discussed in Chapter 1.

Three different levels of interpretation in science

In the first chapter of Gr. 9 Matter and Materials, we learnt that scientists interpret chemical reactions on three different levels. Those three levels are:

  • the macroscopic level;
  • the submicroscopic level; and
  • the symbolic level.

Check whether you still remember what each level refers to, by completing the following table.

When we do the following:

We are operating on this level: (Macroscopic/ submicroscopic/ symbolic)

Observe actual reactions (see, hear, smell, touch, taste).

Describe what we see in words.

Imagine the behaviour of particles during reactions.

Draw pictures of particles in substances.

Write chemical formulae.

Write reaction equations.

When we do the following:

We are operating on this level: (Macroscopic/submicroscopic/symbolic)

Observe actual reactions (see, hear, smell, touch, taste).

Describe what we see in words.

Macroscopic

Imagine the behaviour of particles during reactions.

Draw pictures of particles in substances.

Submicroscopic

Write chemical formulae.

Write reaction equations.

Symbolic

Soon your teacher will demonstrate two reactions, while you will be making observations. Which of the three levels will you be operating at?


The macroscopic level.

The purpose of these demonstrations is to give you a chance to make macroscopic observations of the chemical changes that take place during the reactions. This chapter will also help you to link those macroscopic observations with pictures and equations that you learnt to write in the previous chapter.

The reaction of iron with oxygen

  • combustion

We will be looking at how iron reacts with oxygen. In some cases, you might use steel wool for these experiments. Do you know what steel wool is? It is wire wool made of very fine steel threads. Steel is an alloy made mostly of iron. So, when we look at how steel wool burns in oxygen, we are actually looking at how iron reacts with oxygen.

A metal alloy is a solid mixture of two or more different metal elements. Examples are steel and brass.

http://www.flickr.com/photos/rockandrollfreak/7697586652/
Steel wool spinning creates interesting photos as the iron burns in oxygen and creates orange sparks. http://www.flickr.com/photos/rockandrollfreak/7697586652/
Iron shavings look like sparks when they burn in the blue flame of a Bunsen burner.

You can see a video of steel wool burning here:

Your teacher will perform a demonstration in which iron is burned in air. When a substance burns in air, the reaction is called a combustion reaction. When a substance combusts in air, it is really reacting with oxygen.

The reaction of iron with oxygen

It is recommended that you demonstrate this reaction to the learners, because of the hazards involved when burning metals.

Safety precautions to observe during the demonstrations:

  1. Wear safety goggles and a protective coat.
  2. Exercise caution when burning the steel wool, as sparks may be produced. Learners should be cautioned against standing too close during the demonstration.
  3. Place a clean beaker or watch glass underneath to catch any metal oxide that forms during the reaction. Students can examine the reaction product afterwards to formulate their observations.

MATERIALS:

  • Bunsen burner or spirit burner
  • matches
  • safety goggles
  • steel wool
  • tongs

INSTRUCTIONS:

  1. Your teacher will demonstrate the combustion of iron in oxygen (which is present in air).
  2. You should make careful observations during the demonstration and write these down in the spaces provided below. To guide you, some questions have been provided.

QUESTIONS:

We used steel wool in this demonstration, but what is steel wool mostly made of?


Steel wool is an alloy made mostly of iron. NOTE: The other elements in steel include carbon, manganese, phosphorus, sulfur, silicon, and traces of oxygen, nitrogen and aluminum. Learners do not need to know the names of the other elements in steel wool.

Look at the metal before it is burned. Describe what it looks like.



Learners' observations may include any of the following: The steel wool consists of thin threads of iron. It looks like hair made of metal. Depending on the state of the steel wool, learners may describe it as shiny, or dull grey, metallic, or even rusty. Encourage creative descriptions.

Can you see the oxygen that the metal will react with? Can you describe it?



Oxygen gas can not be seen or directly observed and so it cannot be described.

What do you observe during the reaction? Describe anything you see, hear, or smell.




  • Learners may see the steel wool burning and bright orange sparks falling. They may even notice some smoke.
  • Learners may hear the crackling sound of the steel wool burning.
  • Learners may notice a metallic smell in the air.
  • Learners may experience the heat from the combustion reaction.

What does the product of the reaction look like? Describe it in as much detail as possible.


The product is a reddish-brown, crumbly solid.

Iron oxide is used as a pigment in paints as it comes in a range of browns and reds.

If you think the reaction when iron burns in oxygen is spectacular, the next demonstration will amaze you!

The reaction of magnesium with oxygen

  • camera flash
  • ignite

Your teacher will perform a demonstration in which magnesium is burned in air.

Magnesium burns with a bright white flame.

A video showing magnesium burning in oxygen

The reaction of magnesium with oxygen

It is recommended that you demonstrate the reaction to the learners, because of the hazards involved with burning metals.

Instructions:

  1. Wear safety goggles and a protective coat.
  2. Caution learners not to look directly at the intense white flame produced by the burning magnesium.
  3. Place a clean beaker or watch glass underneath to catch any metal oxide that forms during each reaction. Students can examine the reaction product afterwards to formulate their observations.
  4. You may want to retain the product of the magnesium combustion reaction for a follow-up experiment in the chapter Reactions of acids with metal oxides.

  5. You can also mix the product in water at this stage and test if it is an acid or base.

MATERIALS:

  • Bunsen burner or spirit burner
  • matches
  • safety goggles
  • magnesium ribbon
  • tongs
  • watch glass or beaker

INSTRUCTIONS:

  1. Your teacher will demonstrate the combustion of magnesium in oxygen.
  2. You should make careful observations during the demonstration and write these down in the spaces provided below.

QUESTIONS:

Describe the physical form (shape) of the metal in this experiment.


The magnesium is in the form of magnesium 'ribbon'.

What do we call reactions where a substance burns in air?


Combustion reactions.

How would you describe the physical appearance or colour of the metal before it is burned?



Learners' observations may include any of the following: The magnesium ribbon looks like a thin strip of metal. It looks like metal tape. Depending on the state of the ribbon, learners may describe it as shiny, or dark grey, black, metallic, or even tarnished. Encourage creative descriptions.

Can you see the oxygen that the metal will react with? Can you describe it?


Oxygen gas can not be seen or directly observed and so it cannot be described.

What do you observe during the reaction? Describe anything you see, hear, or smell.




  • Learners may see the magnesium burning with a blinding white light. They may notice some smoke.
  • Learners may hear crackling or hissing as the magnesium burns.
  • Learners may notice a hot, metallic smell in the air.
  • Learners may experience the heat from the combustion reaction.

What does the product of the reaction look like? Describe it in as much detail as possible.


The product is a soft, white, powdery solid.

Magnesium is in group 2 in the Periodic Table. Do you remember that we said that elements in the same group will behave similarly. This means that they will react in a similar way. We have studied how magnesium reacts with oxygen, but calcium, for example, will behave in a similar way. You can watch the video in the visit link to confirm this.

Video showing calcium reacting with oxygen

The following diagram combines the macroscopic, submicroscopic and symbolic representations of the reaction that you have just observed.

To take a photo in the dark, we need a camera flash. Most cameras have built in flashes these days. But, the earliest flashes worked with flash powder that contained magnesium grains. They had to be lit by hand and burned very brightly, for a very short period.

http://en.wikipedia.org/wiki/File:1909\_Victor\_Flash\_Lamp.jpg
A photographer using an antique camera and flash that works with magnesium powder. http://en.wikipedia.org/wiki/File:1909_Victor_Flash_Lamp.jpg

Now that we have made our macroscopic observations of the two reactions, we are ready to write about these reactions in scientific language.

The general reaction of metals with oxygen

  • word equation
  • picture equation
  • chemical equation
  • reactants
  • product
  • metal oxide

Let us start by writing word equations for the two reactions that we have just performed. Word equations are often easier to write than picture equations or chemical equations and so they are a good starting point when we want to write reactions.

Write the word equation for the reaction between iron and oxygen and for the reaction between magnesium and oxygen.



The word equations are:

  • iron + oxygen → iron oxide

  • magnesium + oxygen → magnesium oxide

You can write these on the board.

The word equation

We can write a general word equation for reactions in which a metal reacts with oxygen:

metal + oxygen → metal oxide

When we use words to describe a reaction, we are still operating on the macroscopic level. Next, we are going to translate our word equation to a picture equation.

The picture equation

When we represent a chemical reaction as a particle diagram, such as in the picture equation below, we are operating on the submicroscopic level.

Can you identify the reactants in the above equation? The purple atoms are magnesium and the oxygen atoms are red. Write down the name and chemical formula of the product of the reaction.

The product is magnesium oxide (MgO)

The picture is not the same for all reactions of metals with oxygen.

The chemical equation

We can go further and translate the picture equation for the reaction between magnesium and oxygen to a chemical equation:

2 Mg + O2→ 2 MgO

Since the chemical equation consists of symbols, we can think of this as a symbolic representation.

Can you remember what the numbers in front of the formulae in the chemical equation are called? Can you remember what the numbers inside a chemical formula are called?


Coefficients and subscripts, respectively.

As we have said, the metals in the same group will react in the same way as each other with oxygen. So, calcium reacts with oxygen in the same way as magnesium reacts with oxygen. The chemical equations also show similarities. The chemical equation for the reaction between calcium and oxygen is:

2Ca + O2→2CaO

What is the product called in this reaction?


Calcium oxide.

What group are calcium and magnesium from?


Group 2.

A metal oxide has the the general formula MO or M2O. In the formula, M represents a metal atom and O represents oxygen. We can therefore say that metals from Group 2 will react with oxygen and have the following general equation, where M represent a Group 2 metal:

2M + O2→2MO

Metal oxides of the types M2O3 and MO2 also occur, but we will limit our discussion to the first two types.

To know whether MO or M2O will be the correct formula, here are two simple rules for you to remember:

This is a suggested way to assist learners to write the formulas. Once learners have learnt about valencies in Gr. 10-12, they will be able to use this information to write the formulas of compounds. for now though, this is sufficient.

  1. Metal oxides from group 1 on the Periodic Table will have the formula M2O.

Can you write two examples? Look at the Periodic Table at the front of the book, pick any two metals from group 1 and write their formulae using this rule.



Any two of the following: Li2O, Na2O, K2O, Rb2O, Cs2O

  1. Metal oxides from group 2 will have the formula MO.

Can you write 2 examples?



Any two of the following: BeO, MgO, CaO, SeO, BaO

Group 1 metals are referred to as the Alkali Metals and Group 2 metals are referred to as the Alkaline Earth Metals.

Iron is from Group 8. Here is the picture equation of the reaction between iron and oxygen (iron is green and oxygen is red).

Write the chemical equation and word equation for this reaction underneath the picture equation.

Learners should write the following in line with the respective pictures in the above diagram:

  • iron + oxygen → iron oxide

  • 4 Fe + 3 O2 → 2 Fe2O3

In the next section, we are going to return to the macroscopic world to see another example of the reaction between iron and oxygen that you should be very familiar with - the formation of rust.

The formation of rust

  • rust
  • corrosion
  • corrosive
  • rust-resistant
  • steel

Do you know what rust is? The pictures below will provide some clues.

http://www.flickr.com/photos/flattop341/347445202/
Different objects which rust. http://www.flickr.com/photos/flattop341/347445202/

The reaction between iron and oxygen in air

Here is a suggested activity for you to show how rust forms. This is not required by CAPS. It can be set up as a demonstration. You can then compare this reaction with the one that you did previously where iron was burned in oxygen in a combustion reaction.

This experiment will require a place where it can remain undisturbed for two or three days. It may be worth setting up this experiment at the start of this section. Take note: The test tube may be difficult to clean at the end of this experiment.

MATERIALS:

  • test tube
  • clamp
  • retort stand
  • dish
  • iron filings
  • water

INSTRUCTIONS:

  1. Rinse a test tube with water to wet the inside.
  2. Carefully sprinkle a spatula of iron filings around the sides of the test tube.
  3. Invert the test tube in a dish of water. Use a clamp attached to a retort stand to hold the test tube in place.
  4. Over the three days the water must remain above the lip of the test tube.

Here is a simple diagram showing the experimental setup with the clamp holding the test tube upright.

QUESTIONS:

What do the iron filings look like at the start of the experiment?


They are a silvery colour.

What are the reactants in this experiment?


Iron and oxygen (and water).

Is there something present that is aiding or speeding up the reaction?


The water.

What does the product look like at the end of the reaction?


It is a browny, red colour.

Rust is a word to describe the flaky, crusty, reddish-brown product that forms on iron when it reacts with oxygen in the air.

When your teacher burned the iron earlier, it reacted quickly with oxygen to form iron oxide. Here is a picture of iron oxide to remind you what it looked like.

A sample of iron oxide.

Rust is a form of iron oxide

When iron is exposed to oxygen in the air, a similar reaction occurs, but much more slowly. The iron is gradually 'eaten away' as it reacts slowly with the oxygen. Under wet conditions iron will rust more quickly.

Rust is actually a mixture of different oxides of iron, but the Fe2O3 of our earlier example is an important part of that. The rusting of iron is actually a good example of the process of corrosion.

Remind learners of where else they have heard the term 'corrosive' used before in Matter and Materials. It is used to describe strong acids and bases which learners were first introduced to in Gr. 7 Matter and Materials and will look at again later in this term.

Rusting tends to happen much faster near the ocean. Not only are there water droplets, but these droplets have salt in them and this makes them even more corrosive. Rusting also happens more quickly in the presence of acids. Inside laboratories, or factories where acids are used or stored, the air is also very corrosive. When the air in a specific area contains moisture mixed with acid or salt, we refer to the area as having a corrosive climate.

http://www.flickr.com/photos/mikebaird/4585328947/
An abandoned car quickly rusts and corrodes near the sea. http://www.flickr.com/photos/mikebaird/4585328947/

If you live in a corrosive climate, for example near the ocean, it is often better to make the window frames and doors of your house from wood instead of iron and steel, because wood does not rust. Many people also use aluminium as this metal does not rust.

The problem with rust

Rust is a natural process and its effects can be quite beautiful.

http://www.flickr.com/photos/lizjones/449708229/
A garden sculpture that was intended to rust to give it more texture. http://www.flickr.com/photos/lizjones/449708229/

However, iron and rust (iron oxide) are completely different materials and therefore have different properties.

Why is rust a problem?

This links to what learners have done in previous grades about the properties of materials.

Let's imagine we have manufactured something out of iron. What properties of iron do we want to take advantage of?



Iron is a metal, so it is hard, strong and flexible.

What objects do you think we make out of iron where these properties are desirable?



Tools, locks, hinges, screws and nails, garage doors... the list of items is almost endless!

When an item is made of iron, we might want to protect it from rust, to prevent it from losing those desired properties. Do you think the rusty chain and door handle in the following photos will be as strong and flexible as when they were new? Why not?

http://www.flickr.com/photos/a2gemma/2373078360/
A rusted chain. http://www.flickr.com/photos/a2gemma/2373078360/
http://www.flickr.com/photos/49889874@N05/4883527730/
A rusted door hinge. http://www.flickr.com/photos/49889874@N05/4883527730/



No, they will not be as strong. Rust is a different compound to the element iron and so it has different properties. It starts to weaken the objects.

You might have learnt in previous grades that iron can be strengthened, and made more resistant to rust, by mixing it with other elements to turn it into steel.

Steel is used in the construction of buildings, because it is very strong. Steel is not completely rust-resistant, however, and needs to be protected against rust, especially in moist and corrosive climates.

http://www.flickr.com/photos/ell-r-brown/5375682861/
A building under construction. You can see the framework made of steel. http://www.flickr.com/photos/ell-r-brown/5375682861/
http://www.flickr.com/photos/sbeebe/5225048839/
Steel reinforcement to support a building. As you can see, steel can also rust. http://www.flickr.com/photos/sbeebe/5225048839/

In the next section, we will learn about the different ways in which iron and steel can be protected against rust.

Ways to prevent rust

  • collide
  • barrier
  • exposed
  • porous
  • penetrate
  • chromed metal
  • galvanised metal
  • galvanise
  • oxidise

Rust forms on the surface of an iron or steel object, when that surface comes into contact with oxygen. The oxygen molecules collide with the iron atoms on the surface of the object, and they react to form iron oxide. If we wanted to prevent that from happening, what would we have to do?


We would need to put something between the oxygen and iron so they cannot make contact.

Paint provides a barrier to rust

If we wanted to prevent the iron atoms and oxygen molecules from making contact, we would need to place a barrier between them. That is what we are doing when we paint an iron surface to protect it from rust.

Paint is not the ultimate barrier, though. If the paint surface is scratched, or it starts to peel off, the metal will be exposed and rust can still form.

Other metals as barriers to rust

Rust is a porous material. This means that air and water can penetrate through the rust on the surface of the object to reach the iron underneath. The iron will continue to corrode even if it has a thick layer of rust covering it. So even though the iron surface is covered, it is not protected, because the oxygen molecules can still reach the iron to react with it.

There are a number of other ways to stop or slow down rust. One way to protect the iron surface is to cover it with a metal that does not corrode, like chromium, for instance. Taps and bathroom fittings are often made of iron that has been 'chromed'. They have been covered with a layer of chromium to protect the iron surface from contact with the air.

http://www.flickr.com/photos/a\_mason/3212274/
Chromed taps in a basin. http://www.flickr.com/photos/a_mason/3212274/

Ask learners why they think it is especially important for taps in bathrooms and basin to be protected from rust. This is because they are in a moist, humid environment and water makes iron more prone to rust.

Zinc also reacts with oxygen to form zinc oxide:

2 Zn + O2→ 2 ZnO

What group is zinc in?


Group 12.

Zinc is in a different group to iron on the Periodic Table. This tells us that it does not react the same way as iron does with oxygen.

Zinc oxide (ZnO) is not a porous oxide, but forms a dense protective layer that cannot be penetrated by oxygen or water. Iron can be coated with a thin layer of zinc in a process called galvanising.The zinc layer quickly reacts with oxygen to become zinc oxide. This layer protects the zinc underneath it from being further oxidised. It also protects the iron underneath the zinc from contact with oxygen.

Corrosion and rust (video)

The following diagram shows a segment of galvanised steel, with a scratch in the protective coating. What do you think will happen to the steel that is exposed to the air by the scratch in the coating?


The exposed steel will rust over time.

A segment of galvanised steel, showing damage to the zinc coating.

Iron that is galvanised is used for many different purposes. You would most probably have seen it being used as galvanised roof panels or other galvanised building materials, such as screws, nails, pipes, or floors.

Rust formation and how to prevent it (video)

Galvanised panels used for walls or roofs.
http://www.flickr.com/photos/cwisnieski/5947754467/
A galvanised watering can. http://www.flickr.com/photos/cwisnieski/5947754467/
http://www.flickr.com/photos/johnloo/5289139290/
Galvanised nuts and bolts. http://www.flickr.com/photos/johnloo/5289139290/
http://www.flickr.com/photos/ants88/6846263748/
Galvanised flooring. http://www.flickr.com/photos/ants88/6846263748/

In this chapter we learnt how metal oxides form. We saw two demonstrations of reactions in which metals oxides formed as products. Finally, we learnt about a metal oxide (iron oxide or rust) from our everyday experience as well as ways to prevent objects from rusting, especially those used in buildings and industry.

Cut apple slices turn brown as the iron compounds in the apple flesh are reacting with the oxygen in the air! The reaction is aided by an enzyme in the apple, so dripping lemon juice onto the slices will destroy the enzyme and prevent them from turning brown.

Why do apples turn brown? (video)

If you would like to read more about whay apples turn brown to explain this to your learners in more detail, visit this website: http://humantouchofchemistry.com/why-do-cut-apples-turn-brown.htm

Summary

  • When a metal reacts with oxygen, a metal oxide forms.
  • The general equation for this reaction is: metal + oxygen → metal oxide.

  • Some metals will react with oxygen when they burn. These reactions are called combustion reactions. Two examples of combustion reactions are:

    • Iron reacts with oxygen to form iron oxide:

      4 Fe + 3 O2 → 2 Fe2O3

    • Magnesium reacts with oxygen to form magnesium oxide:

      2 Mg + O2 → 2 MgO

  • Rust is a form of iron oxide and it forms slowly when iron is exposed to air.
  • Iron can be transformed to steel (an alloy), which is more resistant to rust.
  • Rust can be prevented by coating iron surfaces with paint, or with rust-resistant metals such as chromium or zinc.

Concept map

What is the proper name for 'burning'? Fill this into the concept map. Fill in the examples of the metals that you studied in this chapter. You will have to look at the products formed to know where to put which one. Lastly, give two examples of metals that you learnt about in this chapter which do not rust.

This is the completed concept map.

Review questions

Read the sentences and fill in the missing words. Write the missing word on the line below. [9 marks]

  1. A chemical reaction where a compound and oxygen react during burning to form a new product is called a ____________ reaction.


  2. Magnesium + ____________→ magnesium oxide


  3. ____________ + oxygen → iron oxide


  4. copper + oxygen → ____________


  5. Another word for iron oxide is ____________.


  6. Metal that is covered by a thin layers of zinc and zinc oxide is called ____________ metal.


  7. The gradual destruction of materials (usually metals) by chemical reaction with the environment is called ____________.


  8. When the air in a specific area contains moisture mixed with acid or salt, we refer to the area as having a ____________ climate.


  9. The product of the reaction between a metal and oxygen is called a ____________.


  1. combustion
  2. oxygen
  3. Iron
  4. copper oxide
  5. rust
  6. galvanised
  7. corrosion
  8. corrosive
  9. metal oxide

List three materials that can be used to protect iron or steel from corrosion. [3 marks]




  • paint
  • chromium
  • zinc

Complete the table by providing the missing equations for the reaction between iron and oxygen [4 marks]

Word equation

Chemical equation

Picture equation

Word equation

iron + oxygen → iron oxide

Chemical equation

4 Fe + 3 O2 → 2 Fe2O3

Picture equation

Complete the table by providing the missing equations for the reaction between magnesium and oxygen [4 marks]

Word equation

magnesium + oxygen → magnesium oxide

Chemical equation

Picture equation

Word equation

magnesium + oxygen → magnesium oxide

Chemical equation

2 Mg + O2 → 2 MgO

Picture equation

Complete the table by providing the missing equations for the reaction between copper and oxygen [4 marks]

Word equation

Chemical equation

2 Cu + O2 → 2 CuO

Picture equation

Word equation

copper + oxygen → copper oxide

Chemical equation

2 Cu + O2 → 2 CuO

Picture equation

Complete the table by providing the missing equations for the reaction between zinc and oxygen [6 marks]

Word equation

Chemical equation

Picture equation

Word equation

zinc + oxygen → zinc oxide

Chemical equation

2 Zn + O2 → 2 ZnO

Picture equation

Total [30 marks]