What are Semiconductors?

Semiconductors are the foundation of modern technology. Discover how they work and how they’re made.

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Semiconductors work tirelessly behind the scenes to power the world around us – from the technology in your house to the labs curing deadly diseases. They are the foundation of modern technology. Without them, billions of devices across the planet would not function. But what exactly is a semiconductor? And how are they made?

Let’s get right to it. The term semiconductor refers to a material that can be altered to conduct electrical current or block its passage. However, it more commonly refers to an integrated circuit (IC), or computer chip. The most common semiconductor material is silicon. Not surprisingly, silicon is also the main ingredient in computer chips.

Understanding Moore's Law
Semiconductors are as small as your fingernail

As small as a fingernail, semiconductors are arguably the most complex products ever manufactured. A common chip is only about 1 millimeter thick and contains roughly 30 different layers of components and wires called interconnects that make up its complex circuitry. Billions of microscopic switches called transistors make semiconductors work.

A mask engineer taking digital blueprints and converting them to glass templates, called masks, and printing on them with light

1. Mask operations

Engineers take digital blueprints and convert them into glass templates, called masks. They are used in fabrication photolithography, or “printing with light.” As the mask engineers finish each mask, they send them to fabrication factories — or fabs — to begin manufacturing.

What are masks?

Masks are templates used to print circuitry onto a silicon wafer. Mask engineers use computerized drawings from chip designers as blueprints. Those drawings are fed into machines that convert the data into an electronic beam that replicates the circuitry pattern onto 6-by-6 inch pieces of quartz just a quarter-inch thick. These quartz squares are called masks. It can take more than 50 masks to make all the layers of a chip.

Photolithography machine is shinning light through the masks to re-create patterns, and the lens reducing the image, imprinting it onto a wafer's surface

2. Fabrication

Technicians wear bunny suits and use high-tech equipment in clean rooms to create layers of circuits and devices on silicon wafers. Each wafer will contain hundreds of chips. From here, the fab sends the finished wafers to die/sort prep facilities.

What is photolithography?

Silicon wafers are made from the silicon extracted from sand. Techs use photolithography machines to shine light through the masks to re-create patterns. A lens reduces the image and directs it onto a wafer’s surface. This is done repeatedly using a different mask for each layer of transistors and wire connections. Eventually the wafer will be imprinted with hundreds, or even thousands, of tiny individual chips.

Technician rolling a cart of wafers off to assemble an test plants

3. Die/sort prep

In these facilities, diamond saws cut the wafers into thousands of fingernail-size individual rectangles, each called a die or computer chip. Die and sort prep machines cherry-pick the working chips and hand them off to another machine that places them onto reels. These are sent to assembly and test plants.

Every die is tested by a technician wearing a bunny suit. Only the die that are healthy will pass

4. Assembly and test

Here, technicians take each die and test them one last time to make sure they’re healthy and good to go. If they pass, they’re mounted between a heat spreader and a substrate to form a sleek, enclosed package. The exterior package protects die from damage, heat and contaminants. Inside a computer, the package forms electrical connections between the chip and the circuit board.

A warehouse, or hub, houses all finished goods and will be distributed out to customers or other hubs

5. Finished goods warehouses/hubs

From here, logistics professionals may send chips directly to some customers, such as system manufacturers. Or they ship them to global distribution hubs. From these hubs, chips might be sent to original equipment manufacturers in trays or be boxed for retail sale.

Major processor architectures

There are many different kinds of semiconductors – each with its own specialty (and its own acronym). Familiarize yourself with various kinds of semiconductors and learn more about what they do.

Icon of a FPGA, one of the four major types of semiconductors

FPGA

Field-programmable gate array; software-configurable circuits

What they do:
Often used in applications that need to change often, including acceleration, communications, circuit design.

Icon of a GPU, one of the four major types of semiconductors

GPU

Graphics processing unit

What they do:
Make images; accelerate highly parallel operations.

Icon of a CPU, one of the four major types of semiconductors

CPU

Central processing unit (the brain of the computer)

What they do:
Run the computer and all its programs.

Icon of an ASIC, one of the four major types of semiconductors

ASIC

Application-specific integrated circuit

What they do:
One thing very quickly, including deep learning, encryption and network processing.

Semiconductors are everywhere

The average American adult spends more than 12 hours a day using electronics, such as computers, mobile devices, TVs and cars. Those devices are all powered by semiconductors, which improve our lives, increase productivity and drive economic growth.

Smart energy

A/C temp sensors
Efficient logistics systems
LED light bulbs
Monitoring systems
Security devices
Smart home systems
Solar panels

Computing

Computers/laptops
XPUs
Diodes
Microcontrollers
RF transmitters
Wireless HD video

Consumer/IoT

ATMs
Smoke detectors
Internet
Refrigerators
Coffee makers
Video games
Washing machines

Semiconductors are inside of so many things we use each and every day, such as smart energy, computing, IoT, healthcare, transportation and communication

Healthcare

Blood-pressure sensors
Hearing aids
MRIs
Pacemakers
Ultrasound modules
Wireless patient monitors

Transportation

Advanced driver-assistance systems
Diagnostic equipment
Mapping/Sensing
Navigation systems

Communications

Digital cameras
Radios
Scanners
Smartphones
Televisions
Watches/clocks

Intel’s global manufacturing footprint

Intel has wafer labs in Oregon, Arizona, New Mexico, Ohio, Ireland, Germany and Israel. Intel's assembly and test sites are in Costa Rica, Malaysia, Vietnam and Chengdu

Semiconductors are a worldwide business

$10-15B

The approximate cost to build a new semiconductor factory or “fab”

$574.1B

Global semiconductor industry sales in 2022

12K

The number of construction, high-tech and support jobs a semiconductor fab typically creates

4 American
football fields

The equivalent clean room area in one typical semiconductor fab

Summary

  • Semiconductors are the foundation of modern technology. They improve our lives, increase productivity and drive economic growth. 
  • There are many different kinds of semiconductors, each with its own specialty (and acronym). 
  • Semiconductors are probably the most complex products manufactured in the world. A common chip is only about 1 millimeter thick and contains roughly 30 different layers of components and wires called interconnects that make up its complex circuitry. Billions of microscopic switches called transistors make them work.
  • Download this Tech 101

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About Intel

Intel (Nasdaq: INTC) is an industry leader, creating world-changing technology that enables global progress and enriches lives. Inspired by Moore’s Law, we continuously work to advance the design and manufacturing of semiconductors to help address our customers’ greatest challenges. By embedding intelligence in the cloud, network, edge and every kind of computing device, we unleash the potential of data to transform business and society for the better. To learn more about Intel’s innovations, go to newsroom.intel.com and intel.com.

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