Why graphene hasn’t taken over the world...yet

Verge Science

10 Jul 201807:43

Summary

TLDRGraphene, a revolutionary material discovered in 2004, promised to change the world with its exceptional strength, flexibility, and conductivity. While the initial hype envisioned bulletproof armor, ultra-light planes, and space elevators, the reality has been slower to unfold. Despite its remarkable properties, graphene faces challenges in replacing existing technologies like silicon. However, companies like Vorbeck Materials are making strides in its use, from space materials to wearable electronics. While graphene may not be a miracle material, its gradual integration into industry suggests a promising future where it could outperform current alternatives.

Takeaways

😀 Graphene was discovered in 2004 and quickly became a highly publicized wonder material, with promises of revolutionizing multiple industries.
😀 Despite early excitement, many of graphene's expected breakthroughs—such as bulletproof armor and space elevators—have yet to materialize.
😀 Graphene is a single-atom-thick sheet of carbon atoms arranged in a hexagonal pattern, making it incredibly light, strong, flexible, and an excellent conductor of electricity.
😀 The 2010 Nobel Prize was awarded for the discovery of graphene, yet its widespread commercial use has faced delays and challenges.
😀 One major obstacle for graphene is that it needs to be significantly better than existing materials to replace them, which has proven difficult in some fields like electronics.
😀 Graphene's commercial potential lies in its ability to enhance existing materials, such as improving the strength and heat resistance of rubber.
😀 Vorbeck Materials is one of the companies actively mass-producing graphene, incorporating it into products like RFID tags, clothing, and high-strength rubber.
😀 Graphene-based inks are being developed for wearable electronics, with applications in fabrics that can be washed, heated, and twisted without damaging the circuits.
😀 While graphene has faced setbacks, its real-world applications are gradually expanding in fields like industrial products and wearable technology.
😀 The early hype surrounding graphene mirrors past material revolutions, such as the overblown expectations for plastics in the 1920s, which also had a slow and steady impact on industries.
😀 Graphene’s future success depends on whether it can outperform existing technologies on its own merits, regardless of the marketing hype.

Q & A

What is graphene and why is it considered a groundbreaking material?
-Graphene is a single layer of carbon atoms arranged in a hexagonal lattice. It is considered groundbreaking because it has extraordinary properties: it's incredibly light, yet incredibly strong, flexible, and an excellent conductor of electricity, making it suitable for a wide range of potential applications.
How was graphene first isolated in 2004?
-In 2004, researchers in the UK isolated graphene by using simple tools: graphite and tape. They placed the tape on a piece of graphite and peeled it off, removing tiny flakes of graphene, which they then processed with chemicals.
Why has graphene not yet revolutionized industries like electronics and aerospace?
-While graphene has impressive properties, replacing established materials like silicon is challenging. Graphene must offer significant advantages over existing technologies to justify its widespread adoption, which has proven to be a difficult hurdle to overcome in industries like electronics and aerospace.
What are some of the promises made about graphene, and how much of that has been realized?
-Promises about graphene include applications in bulletproof armor, advanced medicine, ultra-light airplanes, and even space elevators. However, many of these promises have not yet been realized, and progress has been slower than expected. Graphene is still being developed for more practical uses, such as in wearables and industrial materials.
How does graphene compare to silicon in electronics?
-Graphene holds promise for use in electronics because of its superior electrical conductivity compared to silicon. However, for graphene to replace silicon, it needs to offer significant improvements, such as enhanced speed and efficiency. The challenge is that graphene hasn't yet demonstrated such clear advantages in this field.
What is the issue with the commercialization of graphene-based products?
-The main issue with commercialization is the difficulty in scaling up the production of high-quality graphene in a cost-effective way. While small-scale graphene production has been successful, making it affordable and practical for widespread use in consumer and industrial products remains a challenge.
What are some real-world applications where graphene is making progress?
-Graphene is being successfully integrated into products such as RFID tags, clothing, and rubber. Companies like Vorbeck Materials are also developing graphene-based inks for wearable electronics that can withstand various environmental conditions like washing and twisting.
What are the challenges in using graphene in the aerospace industry?
-In aerospace, materials must withstand extreme temperature variations. Graphene-infused rubber is being developed to maintain its strength and flexibility in space, where temperatures can fluctuate dramatically. However, producing materials with consistent quality and durability is still an ongoing challenge.
Why do some experts compare graphene’s hype to that of plastics in the 20th century?
-Experts draw comparisons between graphene and plastics because, like plastics in the early 20th century, graphene was initially hyped as a wonder material that would solve multiple problems. However, while plastics did have a significant impact, they also have limitations, and graphene might follow a similar path—fulfilling certain roles but not living up to all the initial promises.
What does John Lettow of Vorbeck Materials say about graphene’s future?
-John Lettow believes that if graphene works well on its own merits, the hype around it won’t matter. He emphasizes that the key is delivering products that work better and last longer, regardless of whether the material is marketed as graphene or not.