Tag Archives: Bin Yu

Lightweight nanomaterial for firefighters’ safety suits

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This piece of research on firefighters’ safety suits comes from Australia’s Nuclear Science and Technology Organisation (ANSTO). A February 3, 2022 article by Judy Skatssoon for governmentnews.com.au describes the work, (Note: Despite the date of the article, the research is from 2021)

Researchers at ANSTO are developing a new highly protective nano-material they believe will produce light-weight safety suits that are perfect for Australian firefighters.

The technology involves the use of super-thin nanosheets made from a new fire and heat-resistant non-organic compound, thermo-hydraulics specialist Professor Guan Heng Yeoh says.

The compound is created from titanium carbide and produces a lightweight coating which can be used in place of traditional fire protection measures. 

A compound extracted from prawn shells, chitosan, is used to bind the nanomaterial together.

I found more details about the work in a January 25, 2022 ANSTO press release, Note: Links have been removed,

Scientists from UNSW [University of New South Wales] and ANSTO have characterised the structure of advanced materials, that could be used as a lightweight fire-retardant filler.

Fire retardant materials can self-extinguish if they ignite. 

A team under Professor Guan Heng Yeoh, Director of the ARC Training Centre for Fire Retardant Materials and Safety Technologies at UNSW and Thermal-Hydraulic Specialist at ANSTO, are working to commercialise advanced products for bushfire fighting, building protection and other applications.    

They investigated a family of two-dimensional transition metal carbides, carbonites and nitrides, known as MXenes.

In research published in Composites Part C, they reported the molecular structure of MXene, using neutron scattering and other advanced techniques.

Because the stability, properties, and various applications of MXene rely heavily on its atomic and molecular structure,  Prof Yeoh and associates conducted a detailed structural and surface characterisation of MXene.

Knowledge from this research provided good insight on how structure affects electrical, thermoelectric, magnetic and other properties of Mxene.

Experiments at ANSTO’s Australian Centre for Neutron Scattering on the Bilby small-angle neutron scattering (SANS) instrument were undertaken to characterise the two-dimensional structure of nanosheets—revealing the thickness of the material and the gaps between layers.

Theoretical modelling was used to extrapolate key information from the SANS data regarding the structural architecture of the titanium carbide nanosheets and investigate the influence of temperature on the structure.

Measurements revealed that MXene that is suspended in a colloidal solution consists of nanosheets of ultrathin multilayers with clear sharp edges.

The material comprises nanolayers, which overlap each other and form clusters of micro-sized units that endow a level of protection.

The nanolayers can be added on top of organic fire-retardant polymers. The total thickness of MXene was found to be 3 nm.

The information was in alignment with observations made using scanning electron microscopy and transmission electron microscopy.

Senior Instrument scientist Dr Jitendra Mata said, “Using SANS is like looking through a keyhole, the keyhole gives you a size indication from 1 nanometre to 500nm.  It may feel like a small size, but it’s actually not – many physical phenomena and the chemical structure occur within that size range.

“There are not many techniques in the world that gives you information about the structure and surface that accurately in a suspension and in films. Also, neutrons are ideal for many in-situ studies.”

Protective suits made with traditional retardant use as much as 30 to 40 per cent carbon compounds to achieve fire-retardant properties, which makes them heavy.

“Because we can use very low concentrations of the two-dimensional material, it comprises only about 1- 5 per cent of the total weight of the final material,” explained Prof Yeoh.

“And because it can be applied as a post-treatment, it doesn’t complicate the manufacturing process.”

When heat comes from above the surface of the material, it is conducted and moved along the nanosheets dispersing it. The nanosheets also act as a heat shield.

“At this point, it takes a lot of time to etch out the aluminium, but there are groups working on upscaling the MXene production process,” said Prof Yeoh.

“We also need to look at the performance and characteristics of the material at higher temperatures up to 800°C,” he added.

At the macro level, early tests have found the material to be an effective fire retardant.

A large team of researchers from the UNSW and ANSTO contributed to the research including first authors, Anthony Chun Yin Yuen and Timothy Bo Yuan Chen and ANSTO instrument scientist, Dr Andrew Whitten.

The versatile material could also potentially be used in energy storage devices.

Here’s a link to and a citation for the paper,

Study of structure morphology and layer thickness of Ti3C2 MXene with Small-Angle Neutron Scattering (SANS) by Anthony Chun Yin Yuen, Timothy Bo Yuan Chen, Bo Lin, Wei Yang, Imrana I.Kabir, Ivan Miguel De Cachinho Cordeiro, Andrew E.Whitten, Jitendra Mata, Bin Yu, Hong-Dian Lu. Guan Heng Yeoh. Composites Part C: Open Access Volume 5, July 2021, 100155 https://doi.org/10.1016/j.jcomc.2021.100155

This paper is open access.

Taking photos and videos in near darkness

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Who hasn’t found wanted to take a picture in a situation where there’s very little light? It seems scientists at SUNY (State University of New York) College of Nanoscale Science and Engineering (CNSE) have found a way to solve the problem. From a Jan. 30, 2014 news item on Azonano,

When the lights went out at the big game, fans and film crews struggled to take a decent picture in the darkness. Those same folks will be cheering the latest research by a team of SUNY College of Nanoscale Science and Engineering (CNSE) scientists, which makes brilliant video and pictures possible even if the lights go out.

Dark and blurry low light photos could soon be a thing of the past, thanks to the development of game-changing ultrathin “nanosheets,” which could dramatically improve imaging technology used in everything from cell phone cameras, video cameras, solar cells, and even medical imaging equipment such as MRI machines.

As a result, this technology is perfectly suited for inclusion in a wide variety of everyday devices, including today’s smartphones, which are often used to take pictures, but suffer from limitations in low light environments. This research could allow even novice photographers to take sharper images, even in the midst of a blackout during the biggest game of the year.

A SUNYCNSE research profile titled: SUNY College of Nanoscale Science and Engineering Scientists Publish Game-Changing Semiconductor Nanosheets Research That Could Revolutionize Cameras in Low-Light Environments provides more technical details about the research,

Leading-edge research by a team of SUNY College of Nanoscale Science and Engineering (CNSE) scientists has been published in ACS Nano after the scientists evaluated ultrathin indium(III) selenide (In2Se3) nanosheets and discovered that their electrical resistance drops significantly when exposed to light. This effect, known as a photoconductive response, can be used to make a photodetector or light sensor, and because the two-dimensional nanosheets exhibited such a strong photoconductive response across a broad light spectrum and simultaneously resist chemical contamination, this research could lead to a revolution in extreme low-light, high-resolution imaging products and applications, such as consumer and professional cameras and video cameras, for example.

The team combined a variety of cutting-edge tools and methods, including scanning electron microscopy (SEM) to identify the nanosheets; atomic force microscopy (AFM) to measure their thickness; X-ray diffractometry (XRD) and selected area electron diffraction (SAED) combined with high-resolution images from transmission electron microscopy (TEM) to examine nano-layer details such as the crystallographic phase and morphology of the sample; and energy-dispersive X-ray spectrometry (EDS) and auger electron spectrometry (AES) to explore the sample’s homogeneity. As the photoconductive material’s properties were characterized, the CNSE research group found that the material is extremely resistant to contamination. Additionally, the team utilized a green LED to direct pulsed light at the nanosheets and found that they exhibited a reliable response to light and an excellent response time between 18 and 73 milliseconds, indicating that In2Se3 nanosheets could be a highly effective material for real-time imaging purposes.

The nanosheets were also tested for the ability to detect light and for light responsivity, or the ratio of generated photocurrent to incident light power. The researchers noted that the photoconductive response of the nanosheets, which had a thickness of 3.9 nanometers, was demonstrably higher than other 2D photoresistors across a broad light spectrum, including Ultraviolet, visible light, and infrared, making them suitable for use in a wide-range of imaging devices.

Here’s a link to and a citation for the paper,

Extraordinary Photoresponse in Two-Dimensional In2Se3 Nanosheets by Robin B. Jacobs-Gedrim, Mariyappan Shanmugam, Nikhil Jain, Christopher A. Durcan, Michael T. Murphy, Thomas M. Murray, Richard J. Matyi, Richard L. Moore, II, and Bin Yu.  ACS Nano (2014), vol. 8, no. 1, pp. 514-21

This is a PDF of the document and is being made available by the researchers and their institution.