Conductive graphene ink wins science photography competition's top prize

Conductive graphene ink wins science photography competition's top prize
The 'Wonder material' graphene is a sheet form of carbon that is a single atom thick. Among its many remarkable properties it is a superb conductor of electricity. However, it is difficult to mass-produce. One way to overcome this problem is to process powdered graphite in alcohol to produce conductive ink, which can be used in inkjet printers to print electrical circuits on paper. Alternatively, other chemicals can be added to it so that it can be used for screen printing on bendable plastic sheets to make components for flexible electronics. The ink in this photo is forced at high pressure through micrometre-scale capillaries made of diamond. This rips the layers apart and we end up with a smooth, conductive material in solution. Credit: James Macleod, University of Cambridge/EPSRC

An image of spectacular swirling graphene ink in alcohol, which can be used to print electrical circuits onto paper, has won the overall prize in a national science photography competition, organised by the Engineering and Physical Sciences Research Council (EPSRC).

'Graphene—IPA Ink', by James Macleod, from the University of Cambridge, shows powdered graphite in alcohol which produces a . The ink is forced at high pressure through micrometre-scale capillaries made of diamond. This rips the layers apart resulting in a smooth, conductive material in solution.

The image, came first in two categories, Innovation, and Equipment & Facilities, as well as winning overall against many other stunning pictures, featuring research in action, in the EPSRC's competition—now in its fourth year. James Macleod, explained how the photograph came about: "We are working to create conductive inks for printing flexible electronics and are currently focused on optimising our recipe for use in different printing methods and for printing onto different surfaces. This was the first time we had used alcohol to create our ink and I was struck by how mesmerising it looked while mixing."

The competition's five categories were: Eureka & Discovery, Equipment & Facilities, People & Skills, Innovation, and Weird & Wonderful. Other winning images feature:

  • A 3D printed gripper which was programmed to lift delicate, geometrical complex objects like a lightbulb, pneumatically rather than using sensors.
  • A scanning electron microscope image showing the surface of a silicon chip, patterned to create a one metre ultra-thin optical wire, just one millionth of a metre wide made into a spiral and wrapped into an area the size of a square millimetre.
  • Researcher Michael Coto with a local student in Vingunguti, Dar es Salaam, Tanzania, testing and purifying polluted water using new solar active catalysts.
  • An image captured on an iPhone 4s through an optical microscope that shows the variety of textures appearing on the surface of a , not dissimilar to pyramids surrounded by a sea of dunes in a desert, but with the size of a human hair.
  • Tiny biodegradable polymer particles resembling golf balls being developed to target infectious diseases and cancers. Only 0.04mm across, they form part of scaffolds which are being studied to see if they can support the growth of healthy new cells.

One of the judges was physicist, oceanographer and broadcaster, Dr Helen Czerski, Lecturer at UCL, she said: "Scientists and engineers are often so busy focusing on the technical details of their research that they can be blind to what everyone else sees first: the aesthetics of their work. Science is a part of our culture, and it can contribute in many different ways. This competition is a wonderful reminder of the emotional and artistic aspects of science, and it's great that EPSRC researchers have found this richness in their own work."

Citation: Conductive graphene ink wins science photography competition's top prize (2017, April 3) retrieved 29 March 2024 from https://phys.org/news/2017-04-graphene-ink-science-photography-competition.html
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