How Much Does Graphene Cost?

Graphene oxide is the foundation of tomorrow’s innovations, with a single-atom-thick carbon sheet that is enhanced by oxygen groups. Having exceptional strength, flexibility, electrical and thermal conductivity, graphene revolutionizes from energy storage to the automotive industry. Remarkable material with extraordinary properties has gained popularity across industries.

However, do you know the actual graphene cost that you are paying nowadays? In the US, the graphene market is projected to hit $85.5 million this year, and it’ll grow rapidly at nearly 29% annually by 2033.

Furthermore, the cost depends on the type of graphene oxide, which typically ranges between $100 and $500 per kilogram. In this blog, we explore the factors that significantly impact the cost of graphene oxide prices.

Factors That Impact the Graphene Cost

Several factors influence the business's decision to increase or decrease the price of Graphene Series Products. Let’s see the factors that force Graphene Oxide Suppliers to charge their costs.

Synthesis Method of Graphene

Understanding how graphene is manufactured is essential to determining the cost of the products. The manufacturing process used by manufacturers to produce graphene has a significant impact on its price. Here are the most well-known methods for producing graphene.

Read Also: Graphene and Its Uses in Organic Solar Cells

Chemical Vapor Deposition (CVD)

It’s a bottom-up approach where carbon atoms are dumped on the substrate to grow a graphene layer by layer with excellent quality. The use of high equipment costs, energy use, and precision requirements makes CVD Graphene expensive.

Liquid Phase Exfoliation (LPE)

A top-down approach that breaks down the bulk graphite into more miniature graphene sheets using solvents. Commonly produces few-layer to multiple-layer graphene in large quantities at a reasonable cost. However, the sheet size and quality in context to the strength are less uniform compared to CVD.

Mechanical exfoliation

Another top-down approach, which is known as the “scotch tape method”. Despite this, it can fabricate nearly perfect single-layer graphene in microscopic quantities. Although the quality is excellent, its poor scalability makes it an impractical and costly option for industrial use. Perhaps research labs can benefit from this manufacturing process for their experiments.

Purity and Forms of Graphene

Graphene costs are never universal and fixed; they vary depending on the form of graphene. Whether the manufacturer produces this material in powder, film, or flakes, they pay according to their specifications. Additionally, the cost varies according to the purity level as well.

Read Also: Graphene and Its Application in Electronics

Powder & Oxides

Products like graphene oxide and graphite oxide are more affordable. Additionally, they are easier to handle in bulk, and professionals utilize them in various applications, including energy storage, composites, and coatings. They are produced from chemical oxidation methods like Hummer’s methods and their modified versions.

Functionalized Flakes

Variants such as Carboxyl Graphene or Graphene on PET substrate fall between these ranges. The substrate flexibility and added surface chemistry maximize the cost compared to powders. However, they become highly valuable in specialized industries such as biotech or flexible electronics.

Films

The high-precision option of graphene has become significantly more expensive due to its complex synthesis processes, such as CVD graphene and Graphene on Copper Foil, which command higher prices. Moreover, these single-layer or few-layer films are produced under an expensive synthesis process.

It is popular among scientists to deliver quality for sensors, electronics, and transparent conductors. A CVD Graphene Supplier may charge more than bulk powders, depending on the layer consistency and thickness. Industries like sensors and semiconductors invest in this graphene to achieve high-performance outcomes.

Quantity of Graphene

Another element that impacts the group’s cost is quantity. Similar to other chemicals and materials, buying graphene in bulk offers cost advantages. Therefore, industries can buy them at cheaper rates from graphene suppliers and fulfill their industrial needs.

Powders are cost-effective, flakes are mid-range, and films are premium, as production complexity and demand directly shape the price per gram.

Read Also: Graphene: A Complete Chemical History

Research & Industrial Difference

Graphene powder is available in various grades tailored to specific applications. For research and experimental applications, scientists and researchers require pure and consistent materials, which are more expensive.

Graphene on copper foil is also a category that bridged the gap between laboratory and industrial demands. Additionally, manufacturers use copper substrates during growth and later convert them into other materials.

In contrast, industrial-grade graphene has slightly lower specifications but still meets industrial standards. So, the purpose of using graphene is also to determine its cost.

Role of Graphene Tensile Strength

Cost alone doesn’t determine the graphene’s usefulness and high performance. The graphene tensile strength measured at over 130 gigapascals (GPa) makes it stronger than other metals like steel, while being much lighter. Despite this, graphene’s strength makes it a perfect option for the aerospace and automotive industries to continue the search for graphene composites despite the higher costs.

Read Also: Graphene: Super Strength for the 21st Century

Graphene Polymer Additives

Businesses do not need pure graphene, which is expensive and time-consuming. Sometimes, they rely on graphene polymer additives to enhance product performance. In some cases, even a small amount can lead to graphene plastic tensile strength improvement, creating a more rigid and durable material. Sports goods manufacturers use the graphene polymer in helmets, bicycles, and tennis racquets.

Wrap Up Things

In a nutshell, the above discussion revolves around how much graphene costs. It entirely depends on the type of graphene, its purity, and the production methods used. Apart from that, bulk powders and oxides may be affordable, while the advanced forms like CVD graphene, graphene on foil, and PET substrates are expensive.

Visit ACS Material today and let us be your reliable supplier of graphene and graphite oxide. Whether you need graph paper for laboratories and industrial scales, we’ll provide it to you at the best prices. Also, don’t forget to connect with us on Facebook and X(Twitter) for the latest updates.

FAQ

Q. How do I buy my first graphene stock?

A. Start your process by understanding the market and researching companies that produce or use the product or service graph. Afterward, decide how you want to invest and place an order in the market or a limit order. Also, must track the industry, not only the stock, as we know group management is still emerging and begin with small and long-term positions.

Q. What are the current prices of graphene?

A. The prices vary depending on forms, their uses, synthesis, and graphene strength. However, the price range for graphene oxide is $100 to 250$ per gram for research-grade materials. Additionally, graphene product suppliers offer premium CVD graphene or graphene on substrates at more than 3 to 10 times the cost. Visit ACS Material to check the accurate pricing of graphene series products.

Q. What is the major challenge of graphene?

A. The challenge for graphene is the difficulty in producing bulk quantities of high-quality material at a low cost. Other challenges include the production scale, quality, and defects.

Q. How many grams are in one pound of graphene?

A. One pound of graphene is equal to 454 grams of material. It will help you to buy the product for research and lab work where you need a smaller quantity.

Q. What are the applications of graphene polymer additives?

A. Graphene polymer additive applications are diverse, improving the strength of polymers, conductivity, and barrier properties, making it perfect for aerospace, electronics, tissue engineering, and energy storage.