We use cookies to enhance your experience. By continuing to browse this site you agree to our use of cookies. More info.

The development of a stable and high-performance MXene membrane for the treatment of drinking water is reported in a recent study published in the Journal of Membrane Science.

Study: Preparation and evaluation of a high performance Ti3C2Tx-MXene membrane for drinking water treatment. Image Credit: Alina Kruk/Shutterstock.com

MXenes are used in the design of rechargeable batteries, sodium-ion fuel cells, and superconductors due to their high conductance and remarkable electrochemical efficiency. In applications related to the environment, MXenes can be employed as catalysts or co-catalysts for photo electrocatalytic water separation and electrocatalytic carbon dioxide reduction, as well as the removal of contaminants from water, such as toxic metal ions, coloring agents, and nuclear waste.

To date, titanium carbide (Ti3C2Tx) is the most researched group of MXenes, having been developed as a membrane substance for water filtration and detoxification. According to recent research, the two-dimensional membrane created by layering MXene nanofibers has uniform and controlled transmission channels, numerous high specific surface areas, and hydrophilic qualities, which can improve water transmission and efficiently screen contaminants in the water.

The worldwide usage of water supplies is growing at a rate of around 1% annually, and this trend is expected to continue as water requirement rises and the effects of climate change deepen. Owing to rising water contamination and water scarcity, drinking water supplies have had to be derived from diverse reservoirs, which are typically contaminated by various pollutants.

The membrane filtration technique has emerged as a viable industrial option in the area of water purification due to its low cost, excellent performance, and ease of use. However, these membranes still face significant challenges and hurdles, such as inadequate contaminant rejection, poor mechanical qualities, high power consumption, and the limited chemical stability of certain polymeric membranes. As a result, MXenes nanosheets provide an appealing alternative to standard membranes for water treatment applications.

Previous research has shown that corrosion of multi-layer or single-layer Ti3C2Tx-MXene converts it to undesirable titanium oxide (TiO2) in both moist air and water. A pure MXene film, like graphene oxide (GO), is susceptible to swelling in the hot and humid environment, which has a significant impact on its ability to retain contaminants. Thus, it is critical to investigate MXene's water durability since water absorption is unavoidable in many actual application settings, whether in the manufacturing or application stages.

As a result, a strategy for protecting the MXene mixture against degradation should be developed to assure its long-term use in an aquatic environment. High stability (including stable interlayer distance and barrier morphology) is required for the membrane to be employed effectively in the practical filtration system and for long-term operation.

In this study, the researchers described a new approach for making an aluminum ion cross-linked MXene-ascorbic acid membrane that stabilizes MXene interlayer separation, prevents swelling, and improves MXene corrosion protection. The connection mechanism between aluminum ions, ascorbic acid, and the MXene sheet was investigated, along with the linkage between membrane structure and membrane efficiency, treatment effectiveness (pollutant persistence), and membrane long-term durability.

The absorption of ascorbic acid on MXene considerably reduced its degradation, extending not only the storage period but also the life span of the MXene coating. In comparison to the unprocessed MXene substrate, intercalated titanium and aluminum membrane (MVCAl) functioned well in the 30-day stability study after crosslinking with aluminum ions.

Furthermore, the MVCAl had a remarkable dye rejection rate of 99.25 percent, with just 7.94 percent retention. During forward filtration, the MVCAl membrane efficiently blocked sodium chloride and magnesium chloride transmembrane transfer. In one hour, the penetration of sodium chloride was almost 0.065%. Additionally, MVCAl barely swelled in water, indicating that it possessed a significant anti-swelling function.

In this work, the researchers used ascorbic acid and aluminum ion binding to produce and evaluate an MXene membrane with high swelling resilience and substrate refusal.  The simple and uncomplicated technique described in this work for manufacturing MXene sheets is expected to pave the way for future practical uses of MXene-based membranes in saltwater distillation and other water purification industries.

Liu, X. et al. (2022). Preparation and evaluation of a high-performance Ti3C2Tx-MXene membrane for drinking water treatment. Journal of Membrane Science. Available at: https://www.sciencedirect.com/science/article/pii/S0376738822002162?via%3Dihub

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.

Hussain graduated from Institute of Space Technology, Islamabad with Bachelors in Aerospace Engineering. During his studies, he worked on several research projects related to Aerospace Materials & Structures, Computational Fluid Dynamics, Nano-technology & Robotics. After graduating, he has been working as a freelance Aerospace Engineering consultant. He developed an interest in technical writing during sophomore year of his B.S degree and has wrote several research articles in different publications. During his free time, he enjoys writing poetry, watching movies and playing Football.

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

Ahmed, Hussain. (2022, April 11). Significant Improvements to MXene Water Filtration Membranes. AZoNano. Retrieved on September 03, 2022 from https://www.azonano.com/news.aspx?newsID=38959.

Ahmed, Hussain. "Significant Improvements to MXene Water Filtration Membranes". AZoNano. 03 September 2022. <https://www.azonano.com/news.aspx?newsID=38959>.

Ahmed, Hussain. "Significant Improvements to MXene Water Filtration Membranes". AZoNano. https://www.azonano.com/news.aspx?newsID=38959. (accessed September 03, 2022).

Ahmed, Hussain. 2022. Significant Improvements to MXene Water Filtration Membranes. AZoNano, viewed 03 September 2022, https://www.azonano.com/news.aspx?newsID=38959.

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

In this interview, we discuss a nanoparticle ink used to produce low-cost printable perovskite solar cells, helping to catalyze the technology transition toward commercial viable perovskite-based devices.

We speak with researchers behind the latest advancement in graphene hBN research that could boost the development of next-generation electronic and quantum devices.

AZoNano speaks with Dr. Laurene Tetard from the University of Central Florida about her upcoming research into the development of nanotechnology that can detect animal-borne diseases. The hope is that such technology can be used to help rapidly control infected mosquito populations to protect public

The Filmetrics R54 advanced sheet resistance mapping tool for semiconductor and compound semiconductor wafers.

This product profile describes the latest nano-particle analyzer "thesis particle size analyzer" and its key features.

The Filmetrics F40 turns your benchtop microscope into an instrument for measuring thickness and refractive index.

AZoNano.com - An AZoNetwork Site

Owned and operated by AZoNetwork, © 2000-2022