Title
Additive nanomanufacturing using nanoscale printing

CoPED ID
c6d2c7f3-498e-472b-a9c6-561262303060

Status
Closed


Value
No funds listed.

Start Date
Sept. 30, 2017

End Date
Sept. 29, 2021

Description

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Regarding the general direction outlined above, the project will begin by exploring different approaches to combine (i) Electrohydrodynamic-Inkjet Printing, (ii) Scanning Probes and (iii) Nanofluidics, if applicable, to additively pattern on surfaces. One of the approaches we discussed is to utilize probes produced by cytosurge to a) Replicate the success the company has had in patterning liquids and b) to extend this work to both thermally and electrically actuate materials and pattern them in either liquid or evaporated form.

Overall, the aims of this project are to come up with a range of manufacturing techniques at the nanoscale that will enable us to have desktop set-ups that can evaporatively print materials additively, as well as easily etch materials without use of a mask in a laboratory setting. The goal is to vastly simplify the nanofabrication process, which currently relies on lithography. Although lithography is a wildly successful process, it is now known that these processes are very environmentally unfriendly (with estimates for a 2 g chip requiring 1.6 kg of fossil fuels to produce by the UN). Therefore, although well suited to mass manufacturing identical components, innovation on smaller batches of components is non-existent for
complex nanoscale devices. Our goal is to enable "bespoke" manufacturing of such components with lower batch sizes. This project
will contribute towards that goal as part of a larger effort within the research group.

It will also train the DPhil student in a range of the high demand skills such as lithography, device design and modeling, characterization at the nanoscale, data analysis and report writing as well as the ability to design and run experiments independently.

This is well aligned to EPSRC's strategy of "Make it local, make it > bespoke". It also has the capability to let small design houses that UK has to really test prototype devices and retain more value through the value chain. Potential collaborators as part of the larger EPSRC Fellowship held by H. Bhaskaran include IBM, Oxford Instruments, MSolv, Bodle Technologies and BASF, but also much larger consortiums under other EPSRC funded projects such as the Wearable and Flexible Technologies Consortium (WAFT, www.waftcollaboration.org). This research is aligned to EPSRC's Manufacturing the future theme, as well as the Engineering and Physical Sciences remits. With a background in engineering, the projects fits very well to the skills of the student, who has the opportunity to contribute in a uniquely creative manner towards this exciting research area.

EPSRC's research areas:

Engineering
Information and communication technologies (ICT)
Manufacturing the future
Physical sciences
Research infrastructure

Harish Bhaskaran SUPER_PER

Subjects by relevance
  1. 3D printing
  2. Manufacturing engineering
  3. Materials (matter)
  4. Projects
  5. Manufacturing

Extracted key phrases
  1. Nanoscale printing
  2. General direction
  3. Complex nanoscale device
  4. Additive
  5. Use
  6. Large EPSRC Fellowship
  7. Project
  8. Device design
  9. Different approach
  10. Exciting research area
  11. Small design house
  12. Etch material
  13. Manufacturing technique
  14. Research group
  15. High demand skill

Related Pages

UKRI project entry

UK Project Locations