Info
Info
News Article

Exfoliation Method Paves The Way For Photonics And Electronics

The versatility of new technique for materials shows promise as a new benchmark in exfoliation chemistry of two-dimensional chalcogenides
A team of scientists from the National University of Singapore (NUS) has developed a method to chemically exfoliate molybdenum disulphide crystals, into high quality monolayer flakes, with higher yield and larger flake size than current methods.

The exfoliated chalcogenide compound flakes can be made into a printable solution, which can be applied in printable photonics and electronics.

This breakthrough, led by Loh Kian Ping, a professor who heads the Department of Chemistry at the NUS Faculty of Science, and is also a principal investigator with the Graphene Research Centre at the Faculty, has generic applicability to other two-dimensional chalcogenides. These include tungsten diselenide and titanium disulphide, and results in high yield exfoliation for all of these two-dimensional materials.

The NUS team collaborated with scientists from the Ulsan National Institute of Science and Technology in Korea, and the findings were first published online in prestigious scientific journal Nature Communications on 2nd January 2014.

Demand for high efficiency exfoliation method

Transition metal dichalcogenides, formed by a combination of chalcogens, such as sulphur or selenium, and transition metals, such as molybdenum or tungsten, have recently attracted great attention as the next generation of two-dimensional materials due to their unique electronic and optical properties, for applications in optoelectronic devices such as thin film solars, photodetectors flexible logic circuits and sensors.

However, current processes of producing printable single layer chalcogenides take a long time and the yield is poor. The flakes produced are of submicron sizes, which make it challenging to isolate a single sheet for making electronic devices.

As most applications require clean and large-sized flakes, this pinpoints a clear need to explore new ways to make high quality single-layer transition metal dichalcogenides with high yield.

Breakthrough in production

To address the production bottleneck, the NUS team explored the metal adducts of naphthalene. They prepared naphthalenide adducts of lithium, sodium and potassium, and compared the exfoliation efficiency and quality of molybdenum disulphide generated. The processing steps are detailed below.

Schematic of pre-exfoliation, intercalation and exfoliation processes



a. Bulk molybdenum disulphide crystal was expanded by decomposition of hydrazine

b.The expanded molybdenum disulphide reacted with sodium naphthalenide to form an intercalation sample, then exfoliated into single layer sheets by immersing in water.

c. Scanning electron microscopy image of single layer molybdenum disulphide on silicon dioxide

d. Atomic force microscopy image of single layer molybdenum disulphide on silicon dioxide

e. Bulk single crystal molybdenum disulphide

f. Pre-exfoliated molybdenum disulphide

g. Sodium-exfoliated single layer molybdenum disulphide dispersion in water


Using a two-step expansion and intercalation method, the researchers were able to produce high quality single-layer molybdenum disulphide sheets with unprecedentedly large flake size.

The researchers also demonstrated that the exfoliated molybdenum disulphide flakes can be made into a printable solution, and wafer-size films can be printed, as the good dispersion and high viscosity of the flakes render it highly suitable for inkjet printing.

In a comparative analysis, Zheng Jian, the first author of the paper, found that the alkali metal naphthalenide intercalation method applied possesses significant advantages in comparison to the conventional method.



Zheng Jian, demonstrating the printing of Molybdenum disulphide flakes from a solution of the exfoliated flakes



Commenting on the significance of the findings, Loh says, “At present, there is a bottleneck in the development of solution-processed two dimensional chalcogenides. Our team has developed an alternative exfoliating agent using the organic salts of naphthalene and this new method is more efficient than previous solution-based methods. It can also be applied to other classes of two-dimensional chalcogenides."

“Considering the versatility of this method, it may be adopted as the new benchmark in exfoliation chemistry of two-dimensional chalcogenides," he adds.

Further research into printable devices

The fast growing field of printed photonics, electronics and optoelectronics demands high material quality, precise material deposition, and application-specific optical, electrical, chemical, and mechanical properties.

To further their research and to cater to the industry, Loh and his team will be looking at developing inks based on different types of two-dimensional chalcogenides exfoliated by their novel method so as to produce printable optoelectronic devices. They will also be testing the optical non-linear properties of the flakes they have produced.

 



AngelTech Live III: Join us on 12 April 2021!

AngelTech Live III will be broadcast on 12 April 2021, 10am BST, rebroadcast on 14 April (10am CTT) and 16 April (10am PST) and will feature online versions of the market-leading physical events: CS International and PIC International PLUS a brand new Silicon Semiconductor International Track!

Thanks to the great diversity of the semiconductor industry, we are always chasing new markets and developing a range of exciting technologies.

2021 is no different. Over the last few months interest in deep-UV LEDs has rocketed, due to its capability to disinfect and sanitise areas and combat Covid-19. We shall consider a roadmap for this device, along with technologies for boosting its output.

We shall also look at microLEDs, a display with many wonderful attributes, identifying processes for handling the mass transfer of tiny emitters that hold the key to commercialisation of this technology.

We shall also discuss electrification of transportation, underpinned by wide bandgap power electronics and supported by blue lasers that are ideal for processing copper.

Additional areas we will cover include the development of GaN ICs, to improve the reach of power electronics; the great strides that have been made with gallium oxide; and a look at new materials, such as cubic GaN and AlScN.

Having attracted 1500 delegates over the last 2 online summits, the 3rd event promises to be even bigger and better – with 3 interactive sessions over 1 day and will once again prove to be a key event across the semiconductor and photonic integrated circuits calendar.

So make sure you sign up today and discover the latest cutting edge developments across the compound semiconductor and integrated photonics value chain.

REGISTER FOR FREE

VIEW SESSIONS

Info
×
Search the news archive

To close this popup you can press escape or click the close icon.
×
Logo
×
Register - Step 1

You may choose to subscribe to the Compound Semiconductor Magazine, the Compound Semiconductor Newsletter, or both. You may also request additional information if required, before submitting your application.


Please subscribe me to:

 

You chose the industry type of "Other"

Please enter the industry that you work in:
Please enter the industry that you work in:
 
X
Info
X
Info
{taasPodcastNotification}
Live Event