Trials applying nanoparticle formulations of iron and calcium to potatoes have not only improved the uptake of those elements – they have led to earlier flowering, brought harvest forward by two weeks, produced more uniform tubers and raised yields and dry matters, according to Karen Davies, of the School of Science and Technology at Nottingham Trent University.
In five trials yields were raised by 22-25%, dry matter content was increased by 5%, and the iron content was lifted by 5%, she says.
Nanoparticles are tiny – less than 100 nanometers in size (a thousand times less a human hair’s width) – but they have considerable potential in crop production, adds Ms Davies who is working on a PhD project*.
“Dietary anaemia is a huge problem, affecting 46% of people globally, and 25% in the UK. Potatoes are naturally high in iron, with a typical portion supplying as much as two portions of beef steak. Fortified potatoes could be a low cost, safe way of providing 100% of our dietary nutritional requirement.”
Her supervisor Dr Gareth Cave has developed a machine able to produce high outputs of nanoparticles, up to 1kg/hour, making a fertiliser approach potentially viable.
The use of nanoparticles is controversial, says Ms Davies.
“But nanoparticles are all around us in the air we breathe – in dust and some pollen particles to foods such as cornflour and icing sugar.
“The iron oxide liquid [iron III/II] plant feed which I use should be commercially available as a home and garden product in September.
“Iron [III] binds tightly to the soil unlike iron [II] found in commercial Fe-EDTA and other forms of chelated iron.
“I’ve carried out a number of toxicity studies and found the iron [III/II] nanoparticles decrease leaching through the soil strata, stay in the top 15cm of soil and gather around the roots, thus reducing contamination of surrounding watercourses and untreated land.”
Iron (III/II) oxide nanoparticle benefits arise from lower concentrations than current iron chelate applications, says Ms Davies. “So any small amount leached into the environment is minimal compared with what’s currently occurring.”
Toxicity studies show the nanoparticles have no significantly adverse effect on freshwater shrimps, and may even help control soil bacteria which cause soft rots, she adds.
“Work on the environmental fate of all of the nanoparticles I work with is ongoing.”
Her work on potatoes is part of wider research into the impact of various iron, calcium and zinc nanoparticles on other crops including tomatoes, chilies, spring onions and strawberries testing foliar, soil, drench and seed-coating application methods.
“My PhD was originally going to look in depth at how nanoparticles get into potato plants. But having listened to industry it is clear we need to first prove the benefits which can be achieved, and only then look at understanding how it happens, so we can fine-tune it.”
The research has involved hydroponic and greenhouse trials and has been extended into the field through collaboration with Branston PLC and CIP, the International Potato Centre (Centro Internacional de la Papa).
“In this third year the project is repeating trials to substantiate data and to focus on the pathway the iron nanoparticles take to be used by the plant.
“We’ll be using radioactive isotope 59Fe, MRI and synchrotron X-ray methods which haven’t been previously used to analyse potato plant biochemistry.”