5.2: Nets and Surface Area
- Page ID
- 39645
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Let's use nets to find the surface area of polyhedra.
Exercise \(\PageIndex{1}\): Matching Nets
Each of the nets can be assembled into a polyhedron. Match each net with its corresponding polyhedron, and name the polyhedron. Be prepared to explain how you know the net and polyhedron go together.
![clipboard_e26129452696d2ce563e97c6dc83acab5.png](https://math.libretexts.org/@api/deki/files/40580/clipboard_e26129452696d2ce563e97c6dc83acab5.png?revision=1)
![clipboard_e2fe84e8ba074da255a3612dfc67a54fe.png](https://math.libretexts.org/@api/deki/files/40581/clipboard_e2fe84e8ba074da255a3612dfc67a54fe.png?revision=1)
Exercise \(\PageIndex{2}\): Using Nets to Find Surface Area
- Name the polyhedron that each net would form when assembled.
![clipboard_eedd33de2f9a692c858ead5b7ab8fada4.png](https://math.libretexts.org/@api/deki/files/40582/clipboard_eedd33de2f9a692c858ead5b7ab8fada4.png?revision=1)
- Your teacher will give you the nets of three polyhedra. Cut out the nets and assemble the three-dimensional shapes.
- Find the surface area of each polyhedron. Explain your reasoning clearly.
Are you ready for more?
- For each net, decide if it can be assembled into a rectangular prism
![clipboard_efd80fe5d3997781318d80100fb64ba88.png](https://math.libretexts.org/@api/deki/files/40583/clipboard_efd80fe5d3997781318d80100fb64ba88.png?revision=1)
- For each net, decide if it can be folded into a triangular prism.
![clipboard_e65ac4c53ee191e1c355ba9d4490b6132.png](https://math.libretexts.org/@api/deki/files/40584/clipboard_e65ac4c53ee191e1c355ba9d4490b6132.png?revision=1)
Summary
A net of a pyramid has one polygon that is the base. The rest of the polygons are triangles. A pentagonal pyramid and its net are shown here.
![clipboard_ead32de576132efafc64cbfa05ff49b31.png](https://math.libretexts.org/@api/deki/files/40585/clipboard_ead32de576132efafc64cbfa05ff49b31.png?revision=1)
A net of a prism has two copies of the polygon that is the base. The rest of the polygons are rectangles. A pentagonal prism and its net are shown here.
![clipboard_ed03284a1df508639920766f675a6d8c6.png](https://math.libretexts.org/@api/deki/files/40586/clipboard_ed03284a1df508639920766f675a6d8c6.png?revision=1)
In a rectangular prism, there are three pairs of parallel and identical rectangles. Any pair of these identical rectangles can be the bases.
![clipboard_e99744e64c13124d477439cf85d33b186.png](https://math.libretexts.org/@api/deki/files/40587/clipboard_e99744e64c13124d477439cf85d33b186.png?revision=1)
Because a net shows all the faces of a polyhedron, we can use it to find its surface area. For instance, the net of a rectangular prism shows three pairs of rectangles: 4 units by 2 units, 3 units by 2 units, and 4 units by 3 units.
![clipboard_e524466320b921d74640ffb05871c4eed.png](https://math.libretexts.org/@api/deki/files/40588/clipboard_e524466320b921d74640ffb05871c4eed.png?revision=1)
The surface area of the rectangular prism is 52 square units because \(8+8+6+6+12+12=52\).
Glossary Entries
Definition: Base (of a Prism or Pyramid)
The word base can also refer to a face of a polyhedron.
A prism has two identical bases that are parallel. A pyramid has one base.
A prism or pyramid is named for the shape of its base.
![clipboard_e7108ec73bf6caa0fb4009e09514bb486.png](https://math.libretexts.org/@api/deki/files/40570/clipboard_e7108ec73bf6caa0fb4009e09514bb486.png?revision=1)
Definition: Face
Each flat side of a polyhedron is called a face. For example, a cube has 6 faces, and they are all squares.
Definition: Net
A net is a two-dimensional figure that can be folded to make a polyhedron.
Here is a net for a cube.
![clipboard_e51e815d4694b5d662a3af6a051d5b533.png](https://math.libretexts.org/@api/deki/files/40571/clipboard_e51e815d4694b5d662a3af6a051d5b533.png?revision=1)
Definition: Polyhedron
A polyhedron is a closed, three-dimensional shape with flat sides. When we have more than one polyhedron, we call them polyhedra.
Here are some drawings of polyhedra.
![clipboard_e82e940969a487023c1fb8e390a9c3c23.png](https://math.libretexts.org/@api/deki/files/40572/clipboard_e82e940969a487023c1fb8e390a9c3c23.png?revision=1)
Definition: Prism
A prism is a type of polyhedron that has two bases that are identical copies of each other. The bases are connected by rectangles or parallelograms.
Here are some drawings of prisms.
![clipboard_e9b79a5b20b511ac8a74db0d204ecc475.png](https://math.libretexts.org/@api/deki/files/40573/clipboard_e9b79a5b20b511ac8a74db0d204ecc475.png?revision=1)
Definition: Pyramid
A pyramid is a type of polyhedron that has one base. All the other faces are triangles, and they all meet at a single vertex.
Here are some drawings of pyramids.
![clipboard_e890748629d8f36ef7adc3959c1f8b034.png](https://math.libretexts.org/@api/deki/files/40574/clipboard_e890748629d8f36ef7adc3959c1f8b034.png?revision=1)
Definition: Surface Area
The surface area of a polyhedron is the number of square units that covers all the faces of the polyhedron, without any gaps or overlaps.
For example, if the faces of a cube each have an area of 9 cm2, then the surface area of the cube is \(6\cdot 9\), or 54 cm2.
Practice
Exercise \(\PageIndex{3}\)
Can this net be assembled into a cube? Explain how you know. Label parts of the net with letters or numbers if it helps your explanation.
![clipboard_e6bf560afb654628d5cefc32023745415.png](https://math.libretexts.org/@api/deki/files/40589/clipboard_e6bf560afb654628d5cefc32023745415.png?revision=1)
Exercise \(\PageIndex{4}\)
- What polyhedron can be assembled from this net? Explain how you know.
![clipboard_ee90f8b907e8557cfdf3e0a58c2d44d66.png](https://math.libretexts.org/@api/deki/files/40590/clipboard_ee90f8b907e8557cfdf3e0a58c2d44d66.png?revision=1)
- Find the surface area of this polyhedron. Show your reasoning.
Exercise \(\PageIndex{5}\)
Here are two nets. Mai said that both nets can be assembled into the same triangular prism. Do you agree? Explain or show your reasoning.
![clipboard_eb06f8c535786b517863c04dd50f5cc26.png](https://math.libretexts.org/@api/deki/files/40591/clipboard_eb06f8c535786b517863c04dd50f5cc26.png?revision=1)
Exercise \(\PageIndex{6}\)
Here are two three-dimensional figures.
![clipboard_e8f1ee752b170228d2c76dce964d1f875.png](https://math.libretexts.org/@api/deki/files/40592/clipboard_e8f1ee752b170228d2c76dce964d1f875.png?revision=1)
Tell whether each of the following statements describes Figure A, Figure B, both, or neither.
- This figure is a polyhedron.
- This figure has triangular faces.
- There are more vertices than edges in this figure.
- This figure has rectangular faces.
- This figure is a pyramid.
- There is exactly one face that can be the base for this figure.
- The base of this figure is a triangle.
- This figure has two identical and parallel faces that can be the base.
(From Unit 1.5.2)
Exercise \(\PageIndex{7}\)
Select all units that can be used for surface area.
- square meters
- feet
- centimeters
- cubic inches
- square inches
- square feet
(From Unit 1.5.1)
Exercise \(\PageIndex{8}\)
Find the area of this polygon. Show your reasoning.
![clipboard_e3206341bce6e40ec60e6f33d65c07c87.png](https://math.libretexts.org/@api/deki/files/40593/clipboard_e3206341bce6e40ec60e6f33d65c07c87.png?revision=1)
(From Unit 1.4.1)