Editorial Feature

Can Graphene Be Mass Produced?

Graphene is the most extensively researched nanomaterial in recent years, owing to its exceptional properties. Despite its promise, the widespread application of graphene is impeded by the absence of high-quality and cost-effective mass-production methods.

Can Graphene Be Mass Produced?

Image Credit: Plastic Man/Shutterstock.com

Challenges in Mass Producing Graphene

Scalability of Production Methods

The methodologies employed for mass production must align with the requirements for industrial-scale testing, typically involving quantities such as a kilogram of powder or suspension containing graphene flakes (typically micrometer-scale) or a thousand pieces for continuous graphene films (normally larger than millimeter size).1

Cost-Effectiveness

For industrial-scale applications, a delicate balance must exist between graphene quality and production cost. As diverse applications demand varied graphene properties, customizing graphene films to suit specific applications becomes essential.

Conversely, the demand for cost-effective graphene production with tailored properties also propels market growth across various applications.2

Quality and Consistency

Quality control is crucial to graphene mass production, ensuring uniformity and reproducibility across large surface areas and between production batches.

The structural attributes of graphene films dictate critical properties, with the number of graphene layers and domain size emerging as crucial factors. As a result, achieving uniform layers and consistent domain sizes in graphene growth becomes imperative.3

Current Methods for Graphene Production

Chemical Vapor Deposition

Among various methods, graphene films synthesized via Chemical Vapor Deposition (CVD) exhibit superior overall performance, meeting the criteria of high quality, large size, and reasonable cost.

However, the presence of prevalent structural imperfections, such as grain boundaries, point defects, and wrinkles, offsets the advantageous properties of CVD-grown samples compared to mechanically exfoliated samples.4,5

These challenges become more pronounced in large-scale graphene synthesis.

Liquid-phase Exfoliation

Owing to its affordability and abundance, graphite is a promising exfoliation resource. The challenge lies in overcoming the van der Waals interaction between graphene layers while preserving the size of graphene platelets.

Early methods involved simple sonication of graphite in organic solvents or water with surfactants.6 Recently, the efficacy of this method has seen partial enhancement through shear exfoliation instead of sonication.7

Graphite Oxide Reduction

The graphite oxide route is the predominant wet chemical method for producing graphene materials, specifically graphene oxide (GO) and reduced graphene oxide (rGO).8

This method's popularity stems from its potential scalability, high yield, and, most notably, its excellent dispersibility in various solvents, facilitating processability for numerous applications.

Recent Advances from Research

Tour and colleagues revealed a groundbreaking discovery wherein various amorphous carbon materials were rapidly transformed into highly crystalline graphene within a single second through flash Joule heating (FJH).

The process was simple: a carbon source with inherent conductivity was compressed between two electrodes within a quartz or ceramic tube.9

Graphene is also synthesized through FJH, utilizing an electric current to generate high-quality turbostratic flash graphene (tFG). Compatible with waste rubber feedstocks, this process offers a more cost-effective alternative to conventional synthetic techniques.10

Another study proposes combining ball milling with shear-mixing in supercritical CO2 for large-scale graphene production. A continuous exfoliation system has been developed comprising a ball-milling subset driven by a mixer in series with a shear-mixing subset in supercritical CO2.11

Addressing limitations posed by conventional ball milling, the study employed regularly applied shear load feasible for industrial-scale application. The innovative approach uses involute gear teeth profiles instead of spherical surfaces of balls to exfoliate LT-EG/Di-methyl formamide (liquid phase) within the gear contact zone under regularly applied shear load and low temperatures.12

An ultrafast and scalable strategy has been developed for directly exfoliating graphite into high-quality graphene, which strongly favors the formation of single layers and eliminates the need for intercalants, chemicals, or solvents. Graphite exfoliation was achieved using a DC plasma spray setup integrated with a custom-designed inert atmosphere shroud.2

Industrial Advancements

Various efforts have been made to leverage the extraordinary properties of graphene, initially spearheaded by small companies exploring commercial applications of this ground-breaking material.

Today, large consortiums, such as the Graphene Flagship, provide substantial funding and support for bringing graphene products to market.13

Renowned companies have entered the market with graphene-powered supercapacitors, presenting high energy density, low internal resistance, and prolonged application lifetimes.

Skeltontec, a Germany-based company, utilizes its patented Curved Graphene carbon material, which is mass-produced for supercapacitors that surpass industry standards in power and energy density.

Volta-xplore, a leading energy materials company from Canada, employs its SiG graphene-enhanced Silicon anode active material to shape the future of energy storage.14,15

First Graphene, based in the UK, specializes in producing graphene from graphite using the electrochemical exfoliation method. This process involves applying a voltage that drives specific ions to intercalate into the carbon layers of graphite, causing the layers to expand and separate.

The resulting graphene is then utilized in concrete applications, offering promising potential in reducing the cement industry’s carbon footprint by up to 20 % through reduced cement content.16

Graphene manufacturing group (GMG) is also exploring applications in aluminium-ion batteries, heat transfer enhancement, and lubricants using an instant, scalable graphene made from natural gas (methane).17

Companies like Applied Graphene Materials are actively working on graphene dispersions and paints, using bottom-up processes to mass-produce graphene nanoplatelets.18

Graphene Mass Production: Challenges and Innovations

Graphene's commercialization journey will unfold in distinct phases.

In the short term (within five years), applications in the materials sector, such as composites, inks, and coatings, will dominate.

Moving into the mid-term (five to ten years), advancements in the energy sector and optoelectronics are expected, including batteries, solar cells, and sensor technologies.

Over the subsequent five to fifteen years, these applications will expand into various markets, impacting construction materials, water purification membranes, supercapacitor electrodes, flexible solar cells, and autonomous driving systems.

In the long term (fifteen to thirty years), graphene's properties will be harnessed in medical devices, while layered materials will play a pivotal role in quantum technology endeavors.19

More from AZoNano: What is a Graphene Semiconductor?

References and Further Reading

  1. Zhu, Yanwu., et al. (2018). Mass production and industrial applications of graphene materials. National Science Review. doi.org/10.1093/nsr/nwx055
  2. Islam, A., et al. (2021). Ultra-fast, chemical-free, mass production of high quality exfoliated graphene. ACS Nano. doi.org/10.1021/acsnano.0c09451
  3. Kong, W., et al. (2019). Path towards graphene commercialization from lab to market. Nature Nanotechnology. doi.org/10.1038/s41565-019-0555-2
  4. Jia, K., et al. (2021). Toward the commercialization of chemical vapor deposition graphene films. Applied Physics Reviews. doi.org/10.1063/5.0056413
  5. Ciesielski, A., Samorì, P. (2014). Graphene via sonication assisted liquid-phase exfoliation. Chemical Society Reviews. doi.org/10.1039/C3CS60217F
  6. Li, X, et al. (2009). Large-area synthesis of high-quality and uniform graphene films on copper foils. Science. doi.org/10.1126/science.1171245
  7. Paton, KR., et al. (2014). Scalable production of large quantities of defect-free few-layer graphene by shear exfoliation in liquids. Nature Materials. doi.org/10.1038/nmat3944
  8. Sharif, A., et al. (2023). Extensive reduction of graphene oxide on thin polymer substrates by ultrafast laser for robust flexible sensor applications. Applied Surface Science. doi.org/10.1016/j.apsusc.2022.156067
  9. Luong, DX., et al. (2020). Gram-scale bottom-up flash graphene synthesis. Nature. doi.org/10.1038/s41586-020-1938-0
  10. Advincula, PA., et al. (2021). Flash graphene from rubber waste. Carbon. doi.org/10.1016/j.carbon.2021.03.020
  11. Tan, H., et al. (2022). Scalable massive production of defect-free few-layer graphene by ball-milling in series with shearing exfoliation in supercritical CO2. The Journal of Supercritical Fluids. doi.org/10.1016/j.supflu.2021.105496
  12. Yousef, S., Mohamed, A., Tatariants, M. (2018). Mass production of graphene nanosheets by multi-roll milling technique. Tribology International. doi.org/10.1016/j.triboint.2018.01.040
  13. Graphene Flagship. (no date). What is the Graphene Flagship?. [Online] Graphene Flagship. Available at: https://graphene-flagship.eu/ 
  14. Skelton Technologies. (no date). Skelton Materials. [Online] Skelton Technologies. Available at: https://www.skeletontech.com/ultracapacitor-technology
  15. Voltaxplore. (no date). Product. [Online] Voltaxplore. Available at: https://voltaxplore.com/?page_id=2
  16. First Graphene. (2022). Graphene a key driver in race for green cement and concrete. [Online] First Graphene. Available at: https://firstgraphene.net/graphene-a-key-driver-in-race-for-green-cement-and-concrete/
  17. GMG. (no date). Graphene Aluminium-Ion Battery. [Online]. GMG. Available at: https://graphenemg.com/graphene-products/
  18. Applied Graphene Materials. (no date). Products. [Online]. Applied Graphene Materials. Available at: https://www.appliedgraphenematerials.com/
  19. Reiß, T., Hjelt, K., Ferrari, AC. (2019). Graphene is on track to deliver on its promises. Nature Nanotechnology. doi.org/10.1038/s41565-019-0557-0

Disclaimer: The views expressed here are those of the author expressed in their private capacity and do not necessarily represent the views of AZoM.com Limited T/A AZoNetwork the owner and operator of this website. This disclaimer forms part of the Terms and conditions of use of this website.

Rita Joshi

Written by

Rita Joshi

Rita Joshi is presently a Research Scholar at the Indian Institute of Technology, Roorkee, India. With a Master’s degree in physics, her academic journey has been marked by a profound commitment to the field of materials science. Her research interests revolve around nanocoatings and composites, spanning a wide range of applications. In her ongoing doctoral research, she is focused on developing graphene-based coatings tailored for electrostatic dissipation and nanocomposites designed to tackle electromagnetic interference shielding, particularly within the challenging domain of spacecraft. Additionally, she is also engaged in a project in collaboration with the prestigious Indian Space Research Organization (ISRO), India. Her involvement in spacecraft coating research underscores her dedication to impactful, real-world applications. Beyond her research endeavors, she possesses a profound passion for science writing and a keen interest in staying at the forefront of cutting-edge technologies within the field of material science. She firmly believes in the value of simplifying complex scientific concepts to make them accessible to a broader audience. Her goal is to bridge the gap between the intricate world of research and the curiosity of readers by presenting scientific findings in an easily digestible and engaging manner.

Citations

Please use one of the following formats to cite this article in your essay, paper or report:

  • APA

    Joshi, Rita. (2024, April 08). Can Graphene Be Mass Produced?. AZoNano. Retrieved on November 23, 2024 from https://www.azonano.com/article.aspx?ArticleID=6716.

  • MLA

    Joshi, Rita. "Can Graphene Be Mass Produced?". AZoNano. 23 November 2024. <https://www.azonano.com/article.aspx?ArticleID=6716>.

  • Chicago

    Joshi, Rita. "Can Graphene Be Mass Produced?". AZoNano. https://www.azonano.com/article.aspx?ArticleID=6716. (accessed November 23, 2024).

  • Harvard

    Joshi, Rita. 2024. Can Graphene Be Mass Produced?. AZoNano, viewed 23 November 2024, https://www.azonano.com/article.aspx?ArticleID=6716.

Tell Us What You Think

Do you have a review, update or anything you would like to add to this article?

Leave your feedback
Your comment type
Submit

While we only use edited and approved content for Azthena answers, it may on occasions provide incorrect responses. Please confirm any data provided with the related suppliers or authors. We do not provide medical advice, if you search for medical information you must always consult a medical professional before acting on any information provided.

Your questions, but not your email details will be shared with OpenAI and retained for 30 days in accordance with their privacy principles.

Please do not ask questions that use sensitive or confidential information.

Read the full Terms & Conditions.