Kevlar®

by Chris Woodford. Last updated: May 17, 2023.

Nature has given us some amazing materials. There's wood: a material so strong and versatile you can use it for everything from making paper to building houses. There's also wool, with insulation so effective it lets sheep stand outside in the snow all winter. Or how about skin: a material that will repair itself automatically and often completely invisibly in only a matter of days? Truly incredible though these materials are, they're far from perfect for every application, especially in the modern world where the challenges we face are ones nature could never have anticipated. That's why we now rely on synthetic materials such as Kevlar®. It's a plastic strong enough to stop bullets and knives—often described as being "five times stronger than steel on an equal weight basis." [1] It has many other uses too, from making boats and bowstrings to reinforcing tires and brake pads. [2] Let's take a closer look at how it's made and what makes it so tough!

Photo: Kevlar is best known as a protective material, but it's much more versatile than that. This is a piece of woven Kevlar being used as part of a proposed, inflatable "space tent" for use on the Moon or Mars. Photo by Paul Hudson published on Wikimedia Commons under a Creative Commons (CC BY 2.0) licence.

What exactly is Kevlar?

Kevlar is one of those magic modern materials people talk about all the time without ever really explaining any further. "It's made of Kevlar", they say, with a knowing nod, as though that were all the explanation you needed.

Kevlar is simply a super-strong plastic. If that sounds unimpressive, remember that there are plastics—and there are plastics. There are literally hundreds of synthetic plastics made by polymerization (joining together long chain molecules) and they have widely different properties. Kevlar's amazing properties are partly due to its internal structure (how its molecules are naturally arranged in regular, parallel lines) and partly due to the way it's made into fibers that are knitted tightly together. [3]

Photo: Kevlar textiles get their properties partly from the inherent strength of the polymer from which the fibers are made and partly from the way the fibers are knitted tightly together, as shown here in a NASA ballistics test. Picture courtesy of NASA Glenn Research Center (NASA-GRC) and Internet Archive.

Kevlar is not like cotton—it's not something anyone can make from the right raw materials. It's a proprietary material made only by the DuPont™ chemical company and it comes in two main varieties called Kevlar 29 and Kevlar 49 (other varieties are made for special applications). [4] In its chemical structure, it's very similar to another versatile protective material called Nomex. Kevlar and Nomex are examples of chemicals called synthetic aromatic polyamides or aramids for short. Calling Kevlar a synthetic aromatic polyamide polymer makes it sound unnecessarily complex. Things start to make more sense if you consider that description one word at a time:

• Synthetic materials are made in a chemical laboratory (unlike natural textiles such as cotton, which grows on plants, and wool, which comes from animals).
• Aromatic means Kevlar's molecules have a strong, ring-like structure like that of benzene.
• Polyamide means the ring-like aromatic molecules connect together to form long chains. These run inside (and parallel to) the fibers of Kevlar a bit like the steel bars ("rebar") in reinforced concrete.
• Polymer means that Kevlar is made from many identical molecules bonded together (each one of which is called a monomer). Plastics are the most familiar polymers in our world. As we've seen, the monomers in Kevlar are based on a modified, benzene-like ring structure.

Like Nomex, Kevlar is a distant relative of nylon, the first commercially successful "superpolyamide", developed by DuPont in the 1930s. Kevlar was introduced in 1971, having been discovered in the early 1960s by US chemist Stephanie Kwolek (1923–2014), who earned US Patent 3,287,323 for her invention, with Paul Morgan, in 1966. Originally developed as a lightweight replacement for steel bracing in vehicle tires, it's probably best-known today for its use in things like body armor; by the time of Kwolek's death in 2014, one million Kevlar body vests had been sold—and countless lives saved. [5]

How is Kevlar made?

There are two main stages involved in making Kevlar. First you have to produce the basic plastic from which Kevlar is made (a chemical called poly-para-phenylene terephthalamide—no wonder they call it Kevlar). Second, you have to turn it into strong fibers. So the first step is all about chemistry; the second one is about turning your chemical product into a more useful, practical material.

Polyamides like Kevlar are polymers (huge molecules made of many identical parts joined together in long chains) made by repeating amides over and over again. Amides are simply chemical compounds in which part of an organic (carbon-based) acid replaces one of the hydrogen atoms in ammonia (NH3). So the basic way of making a polyamide is to take an ammonia-like chemical and react it with an organic acid. This is an example of what chemists call a condensation reaction because two substances fuse together into one. [7]

Artwork: Kevlar's monomer: C=carbon, H=hydrogen, O=oyxgen, N=nitrogen, — is a single chemical bond, and = is a double bond. This basic building block is repeated over and over again in the very long chains that make up the Kevlar polymer. Source: "US Patent: 3287323: Process for the production of a highly orientable, crystallizable, filament" by Stephanie Kwolek et al.

Kevlar's chemical structure naturally makes it form in tiny straight rods that pack closely together, like lots of stiff new pencils stuffed tightly into a box (only without the box). These rods form extra bonds between one another (known as hydrogen bonds) giving extra strength—as though you'd glued the pencils together as well. This bonded rod structure is essentially what gives Kevlar its amazing properties. (More technically speaking, we can say the Kevlar rods are showing what's called nematic behavior (lining up in the same direction), which is also what happens in the liquid crystals used in LCDs (liquid crystal displays).)

You probably know that natural materials such as wool and cotton have to be spun into fibers before they can turned into useful textile products—and the same is true of artificial fibers such as nylon, Kevlar, and Nomex. The basic aramid is turned into fibers by a process called wet spinning, which involves forcing a hot, concentrated, and very viscous solution of poly-para-phenylene terephthalamide through a spinneret (a metal former a bit like a sieve) to make long, thin, strong, and stiff fibers that are wound onto drums. The fibers are then cut to length and woven into a tough mat to make the super-strong, super-stiff finished material we know as Kevlar. [8]

Artwork: How Kevlar is made. 1) The rodlike Kevlar molecules start off in dilute solution. 2) Increasing the concentration increases the number of molecules but doesn't make them align. At this stage, the molecules are still tangled up and not extended into straight, parallel chains. 3) The wet-spinning process causes the rods to straighten out fully and align so they're all oriented in the same direction—forming what's called a nematic structure—and this is what gives Kevlar its exceptionally high strength. Image based on an original artwork from DuPont's Kevlar Technical Guide (see references below).

What's Kevlar used for?

Kevlar can be used by itself or as part of a composite material (one material combined with others) to give added strength. It's probably best known for its use in bulletproof vests and knifeproof body armor, but it has dozens of other applications as well. It's used as reinforcement in car tires, in car brakes, in the strings of archery bows, and in car, boat, and even aircraft bodies. It's even used in buildings and structures, although not (because of its relatively low compressive strength) as the primary structural material. [9]

Photo: Super-strong Kevlar is best known for its use in body armor—and this photo shows you why: it's a piece of Kevlar after being hit by a projectile. You can see a dent (coming up toward the camera)—but you can't see a hole. You might be bruised by this impact (or suffer what's called a "blunt trauma" injury), but you wouldn't die. Picture courtesy of US Army.

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Find out more

On this website

• Composites materials
• Materials science
• Nomex®
• Nylon

On other sites

• Kevlar Technical Guide: Definitive information from DuPont. This will take you to a 4MB PDF format version of the Technical Guide, which can take a while to download depending on your Internet connection.
• Kevlar's uses and applications: DuPont run through about 20 different common uses of Kevlar, from adhesives to vehicle armor.
• US Patent: 3287323: Process for the production of a highly orientable, crystallizable, filament: This is Stephanie Kwolek and Paul Morgan's original Kevlar patent (filed April 25, 1963 and granted November 22, 1966), which describes various chemical methods for making Kevlar.

Books

For older readers

• Enough for One Lifetime: Wallace Carothers, Inventor of Nylon by Matthew Hermes. Chemical Heritage Foundation, 1996. A dry but nonetheless interesting biography of the inventor of nylon (a material very similar to Kevlar). It gives a good sense of how modern, revolutionary materials tend to be "corporate inventions" rather than the work of single inventors, and how inventors can completely fail to foresee the consequences of their ideas.

For younger readers

• Stephanie Kwolek: Creator of Kevlar by Gail B. Stewart. Greenhaven, 2008. A short, 48-page biography for ages 9–12.
• Girls Think of Everything: Stories of Ingenious Inventions by Women by Catherine Thimmesh. Houghton Mifflin Harcourt, 2000/2018. An inspiring read for young teenagers, keen on STEM. Stephanie Kwolek is covered in a short chapter beginning on page 28.

Articles

Popular science and news

• Kevlar 'Wallpaper' Could Protect Soldiers From RPG Blasts by Jordan Golson. Wired, May 29, 2015. How sheets of Kevlar "wallpaper" could be used to protect buildings and structures.
• Stephanie L. Kwolek, Inventor of Kevlar, Is Dead at 90 by Jeremy Pearce. The New York Times, June 20, 2014. A shortr obituary of the chemical pioneer.
• Armor on the Field: The NFL's Headlong Race to Build the Unbreakable Linebacker by Sean Conboy. Wired, July 9, 2012. Could Kevlar padding help to protect sports competitors from serious injury?
• DuPont wins $900m Kevlar spy case: The Guardian, 15 September 2011. Kevlar is an extremely valuable invention and, like other technological pioneers, DuPont has to fight big legal cases to protect its "intellectual property."
• School uniforms made slash-proof: BBC News, 14 August 2007. Could Kevlar protect children against knife crime?
• Tribute to Inventive Women: BBC News, 27 November 2003. A short article about women inventors, including Stephanie Kwolek.
• Kevlar Enters Spotlight As New 'Miracle Fiber' by Gerd Wilcke. The New York Times, May 13, 1974. How the Times described the early development of Kevlar back in the 1970s.

Technical

• Experimental study of bullet-proofing capabilities of Kevlar, of different weights and number of layers, with 9 mm projectiles by Riaan Stopforth and Sarp Adali. Defence Technology, Volume 15, Issue 2, April 2019, Pages 186–192. It's not always the case that more Kevlar provides greater stopping power for bullets, as this scientific study reveals.
• High-modulus, high-strength organic fibers in Concise Encyclopedia of Composite Materials by Anthony Kelly (ed). Pergamon Press, 1989. This is a great introduction to the chemistry and physical properties of Kevlar and similar materials.

References

1. ↑   Bear in mind that there are many different types of steel, with widely differing properties, and note the part about "on an equal weight basis." DuPont's website is the original source for the claim; for example, on its page Kevlar Fibers. Many books repeat this information; see this selection from Google Books. Checking the Kevlar Technical Guide, we find the tensile strength of both Kevlar 29 and 49 is about 3600MPa, while the ultimate tensile strength of high-strength steels is more like 500–800Mpa.
2. ↑   Kevlar's uses and applications, DuPont.
3. ↑   Kevlar Technical Guide, DuPont, 2017, pp.3–4.
4. ↑   Kevlar Technical Guide, DuPont, 2017, p5. Other varieties include Kevlar 100 (for ropes), Kevlar 129 (for lightweight motorcycle gear), and quite a few more described in Kevlar® Fibers.
5. ↑   According to Kwolek's New York Times obituary, her team's task was "trying to develop a lightweight fiber that would be strong enough to replace the steel used in radial tires."
6. ↑   The source for all the information in this list is the Kevlar Technical Guide, DuPont, 2017.
7. ↑   The formation of Kevlar by condensation polymerization is described in the original Kwolek and Morgan patent: US Patent: 3287323: Process for the production of a highly orientable, crystallizable, filament.
8. ↑   For more on how synthetic fibers are manufactured, and how they get their strength, see "Chapter 4: Synthetic polymeric fibers" in Fibrous Materials by K. K. Chawla, Cambridge, 1998, p.73.
9. ↑   Kevlar's uses and applications, DuPont.
10. ↑   For a simple overview of the effectiveness of different amounts of Kevlar, see the entry "Body Armor" in The Encyclopedia of High-tech Crime and Crime-fighting by Michael Newton, Facts on File, 2003, p.41.