Nanotechnologies for water analysis and treatment

Applications of nanotechnologies for water analysis and treatment

By the AVICENN team – Last added November 2020

Nanotechnologies are used to develop more efficient devices for wateranalysis and treatment. Today, it is difficult to distinguish between applications that are already on the market and those that are only in the research and development stage.
Three areas of application of nanotechnologies to the water domain can be distinguished:

• The detection of contaminants in water
• Water purification
• Soil and water remediation

In the face of these potential innovations, the risks associated with risks associated with the nanomaterials used. This field of application can result in the increase of the presence of manufactured nanomaterials in water and groundwater.

There is also the question of the benefit/risk ratio compared to natural alternatives? Innovation is not only technological, as evidenced by the “nature-based solutions” (N BS) promoted by the United Nations in 2018.

The detection of contaminants in water

Nanotechnologies could have interesting applications in the detection of chemical and biochemical substances in water. At the beginning of 2011, the General Manager of Veolia Environnement’s Research Centres considered that “it is very probably in this field [de l’analyse] that we will soon see an industrialization of nanotechnologies for sampling and specific identification in both chemical and microbiological analysis”¹Interview of Mr. Hervé Suty, General Manager of Veolia Environnement Research Centers, given to Richard Varrault(Waternunc), published in 2011.

Water purification

Nanotechnologies can be used to desalinate water, filter pollutants, reduce limescale and/or treat wastewater. The processes used or envisaged may combine different types of action:

Filtration of undesirable elements (pollutants, microbes, salt):

This would be the most advanced process, especially for membranes; the filters can be made up of:

• of carbon nanotubes, to extract viruses and bacteria from water
• nanostructured membranes or membranes with added nanoparticles or nanocoatings²See in particular:
  – A nanofiltration project to reduce micropollutant discharges from the SOTREMO site has been deployed in Le Mans
  – Suez Environnement has participated in a European research project NAMATECH (2009-2012) on the use of nanoparticles for “particularly promising” membranes cf Interview of Mrs. Zdravka Doquang, Head of Analysis and Health at CIRSEE (Suez Environnement), given to Richard Varrault(Waternunc), published in 2011
  – Veolia Environnement has set up a partnership with the American company NanoH2O to develop membranes for the desalination of sea water: hydrophilic nanoparticles are added to reverse osmosis membranes to promote the passage of water
  – French and American researchers have developed “nanoscopic sieves” cf. Desalinating seawater with nano-scale filters, Laboratoire Interdisciplinaire Carnot de Bourgogne, 29 March 2018
  – In 2018, Arkema is proposing an ultra filtration process with a Kynar® PVDF fluoropolymer using nanometric polymer technologies
  – in China, in 2018, a promise of industrial production of nanofiber membranes by 3D printing by Nano Sun, read more
• attapulgite clay and natural zeolites, available in many parts of the world and having natural pore sizes of nanoscopic size
• nano-sponges that trap contaminants (these can include polyurethane sponges coated with iron oxide nanoparticles or carbon nanotubes and nanosilver)³See for example: – Nanocellulose sponges against oil spills, Industry and Technology, December 9, 2014. Developed by two researchers, Gilles Sèbe of the LCPO at the University of Bordeaux 1 and Philippe Tingaut of the Empa near Zurich, this sponge won the Pollutec Innovative Techniques Award.
  – ⁴Low energy water purification enabled by nanomaterial-coated sponges, Science for Environment Policy, February 2015 (academic paper: Conducting nanosponge electroporation for affordable and highefficiency disinfection of bacteria and viruses in water, Liu, C et al., Nano Letters, 13(9): 4288-93, 2013)

Chemical dissolution of pollutants by oxidation

This with theuse of reactive nanoparticles (titanium, iron oxide for example): nanocatalysts could be used to chemically break down pollutants. For example, titanium oxide nanoparticles are more efficient catalysts than titanium oxide on a macroscopic scale and could be used to destroy contaminants by photocatalysis under UV light.

The extraction of pollutants by magnetization

Magnetic nanoparticles have a large surface area relative to their volume and can therefore easily form chemical bonds with water-borne contaminants – such as arsenic, mercury, lead, oil – and then be extracted with a magnet. Applications are already commercialized and there is a lot of research in this field⁹See in particular:
– Iranian and Finnish researchers have developed an iron oxide nanoparticle-based method to remove nitrate and nitrite from water: see Scientists Present Simple Method to Eliminate Nitrate, Nitrite from Water, Soil, Iran Nanotechnology Initiative Council, February 2015
– Researchers from Rice University in the United States have used rust nanoparticles (iron dioxide) to extract arsenic from water: see Low-Field Magnetic Separation of Monodisperse Fe3O4 Nanocrystals, Yavuz C T et al. Science, 2006.

Or the elimination of bacteria, by using metallic nanoparticles (silver or copper nanoparticles) with antibacterial properties¹⁰Cf Research project: NanoSELECT: Biological nanomaterials to purify water, Sweden, FP7; http://www.cordis.europa.eu/result/rcn/165353_en.html and See also: Hymag’in, a French start-up that makes magnetite nanoparticles to purify contaminated water.

Desalination is also an important issue¹¹See in particular
– in the USA in 2017 a research on a combination of membrane distillation and nanophotonics.
– in 2018 a Chinese publication on a method tested in the laboratory, combining the integration of tellurium nanoparticles in water with plasmonics. The rate of water evaporation is multiplied by three under the effect of the sun’s rays. Thus, in 100 seconds the temperature rises from 29°C to 85°C. The creation of nanoparticles is extremely complex and does not offer any possibility of commercialization at the moment..

Remediation and clean-up

According to a study conducted for Ademe in 2010, the market for depollution was 470 million euros. One possible solution would be to use iron nanoparticles to clean up the soil. From 2009 to 2012, the NanoFreezes research project mobilized the efforts of researchers from CNRS, INERIS and CEREGE.

Researchers from Gisfi (Groupement d’intérêt scientifique sur les friches industrielles) reiterated in March 2019 the interest of nanoremediation. Several nanomaterials such as¹²nano-zeolites, metal oxides, carbon nanotubes and nanofibers, enzymes and various noble metals (mainly bimetallic Fe/Pd or Fe/Pt nanoparticles) and titanium dioxide … have been explored for remediation purposes, but iron nanoparticles remain the most used. They are used to decontaminate water and soil loaded with chlorinated compounds, which are among the most widespread pollutants. They can be injected into the water table and mixed with soils to depths of a dozen meters. In France, as in Canada, studies are funded¹³See in particular:
– Studies continue with Gisfi, the Grand Est region and four European partners (Finland, Greece, Hungary and Italy) in a TANIA program TreAting contamination through NanoremedIAtion (€1,285,735 for work from January 2017 to December 2021).
– In Canada, the Institut national de la recherche scientifique (INRS) and the Université de Montréal received a $338,688 grant from the Ministère de l’Économie et de l’Innovation in 2021 for a Innovative nanomaterial-based water decontamination projectthrough the development of new advanced electro-catalytic processes (ECA). .

By using nanocellulose and/or nanochitin membranes, it would be possible to remove bacteria from water¹⁴Cf research project: NanoSELECT: Biological nanomaterials to purify water, Sweden, FP7. Similarly, a French start-up is manufacturing and promoting nano-magnetite to treat water and clean up soil. .

However, the authors underline the uncertainties about the risks,“the barriers to overcome in terms of regulations and the acceptability of these techniques by companies, customers, elected officials and the public“. The introduction of nanoscale ZVIs into the environment may pose a risk to microorganisms that are the basis of the food chain. The factors and processes affecting ecotoxicity are complex and the potential impact of manufactured nanoparticles on the environment and on human health remains poorly described today. In order to prevent any negative impact of nanoremediation on the environment, it is essential to conduct an appropriate assessment, including studies with these nanoparticles at the ecosystem scale. It remains essential to impose a benefit-risk analysis.