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The Power of ‘Soft’

Published online by Cambridge University Press:  02 February 2016

Sarah Morehead
Affiliation:
Northumbria University School of Design, Newcastle-upon-Tyne NE1 8ST United Kingdom
Raymond Oliver*
Affiliation:
Northumbria University School of Design, Newcastle-upon-Tyne NE1 8ST United Kingdom
Niamh O’Connor
Affiliation:
Freelance Fashion Design, London, UK
Patrick Stevenson-Keating
Affiliation:
Studio PSK, London, UK
Anne Toomey
Affiliation:
Royal College of Art, London
Jayne Wallace
Affiliation:
Northumbria University School of Design, Newcastle-upon-Tyne NE1 8ST United Kingdom
*
*Author to whom correspondence should be sent [email protected]
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Abstract

Over the last decade, the explosion in research and Development associated with nanoscalar materials has continued apace. In parallel with this has been the rapid rise of both sustainable materials and, as a consequence, Natural, Cellular and Responsive material systems. Many of these originate from inorganic, inorganic-organic hybrid composites and polymeric and bio-nano polymeric systems which exhibit intrinsic physico-chemical properties that can be classed as ‘soft’. That is flexible, malleable, lightweight, transparent or semi-transparent and stretchable in character and which can also offer both biocompatible and bioresorbable characteristics essential to useable and sustainable material systems.

This paper describes some of the ways in which we are beginning to understand, explain and exploit ‘soft’ technology. In particular the interactive role of creative design and innovative material science linked through new fabrication methodologies that have, as their common purpose, a focus on compelling Human centred needs. Examples are health, wellness, ambient assistance and urgent improvements in cleanliness, hygiene and nutrition.

Type
Articles
Copyright
Copyright © Materials Research Society 2016 

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References

REFERENCES:

Norman, DA, ‘The design of everyday things’, Publ. MIT Press (2013), ISBN 978-0-262-52567-1Google Scholar
Ashby, M, Shercliff, H and Cebon, D, ‘Materials: Engineering science, processing and design’, Publ. Butterworth-Heinemann (Elsevier imprint) (2014), ISBN 978-0-08-097773-7Google Scholar
Rogers, JA, SomeyaT, and Huang, Y, ‘Materials and mechanics for stretchable electronics’ Science vol. 327, p 16031607 (2010)Google Scholar
Rogers, JA, ‘Materials for semi-conductor devices that can bend, fold, twist and stretch’ MRS Bulletin vol. 39, p 549556 (2014)Google Scholar
Ochoa, Manuel, Rahimi, Rahim and Ziaie, Babak. “Flexible Aensors for Chronic Wound Management.” (2013): 1–1.Google Scholar
Rakibet, Osman O., et al. "Epidermal Passive Strain Gauge Technologies for Assisted Technologies." IEEE Antennas and Wireless Propagation Letters 13.1 (2014): 814817.Google Scholar
Kumar, Prashanth S., et al. "Nanocomposite electrodes for smartphone enabled healthcare garments: e-bra and smart vest." SPIE Nanosystems in Engineering+ Medicine. International Society for Optics and Photonics, 2012.Google Scholar
Mattman, C., Amft, O., Harms, H., Troster, G. Recognizing Upper Body Postures using Textile Strain Sensors. Wearable Computers, 11th IEEE International Symposium (2007).Google Scholar
Stoppa, Matteo, and Chiolerio, Alessandro. "Wearable Electronics and Smart Textiles: A Critical Review." Sensors 14.7 (2014): 1195711992.Google Scholar
Komuro, Nobutoshi, et al. "Inkjet printed (bio) chemical sensing devices." Analytical and bioanalytical chemistry 405.17 (2013): 57855805.Google Scholar
Rogers, J.A., et al. Materials and Mechanics for Stretchable Electronics. Science 327, 1603 AAAS (2010)Google Scholar
Yu, You, Yan, Casey, and Zheng, Zijian. "Polymer-Assisted Metal Deposition (PAMD): A Full-Solution Strategy for Flexible, Stretchable, Compressible, and Wearable Metal Conductors." Advanced Materials (2014).CrossRefGoogle Scholar
Carpi, F, De Rossi, D. "Dielectric elastomer cylindrical actuators: electromechanical modelling and experimental evaluation." Materials Science and Engineering: C 24.4 (2004): 555562.Google Scholar
Oliver, R and Toomey, A, ‘A physical basis for Ambient Intelligence’, Lecture Notes of the Institute for Computer Science, Social Informatics and Telecommunication EngineeringGoogle Scholar
Martinez, R.V. Adv Functional Mater 22.07 2012: 1376 – 1384 ‘Elastomeric Origami: Programmable paper-elastomer composites as pneumatic actuators’Google Scholar
Liu, F and Urban, M.W. Progress in Polymer Science 35 2010:333 ‘Recent advances and challenges in designing stimuli responsive polymers’Google Scholar
‘Additive manufacturing: Opportunities and Constraints’ A roundtable discussion hosted by Royal Academy of Engineering, Publ RAEngng (2013) ISBN 978-1-909327-05-4Google Scholar
‘Material computation: Higher integration in morphogenetic design’ Publ. Architectural Design, Jan/Feb (2012), ISBN 978-0470-973301Google Scholar
Ozsecen, M. Y., Mavroidis, C. "Nonlinear force control of dielectric electroactive polymer actuators." SPIE Smart Structures and Materials+ Nondestructive Evaluation and Health Monitoring. International Society for Optics and Photonics, 2010.Google Scholar
Kuechler, S. Technological Materiality: Beyond the dualist paradigm. Theory, Culture and Society, 25 (2008) 101120 CrossRefGoogle Scholar
Bar-Cohen, Yoseph, and Zhang, Qiming. Electroactive polymer actuators and sensors. MRS bulletin 33.03 (2008): 173181.Google Scholar
Oliver, R.’Towards’Soft Machines’ and Future Ways of Living’ Design Specks (2013) 1822 ISBN:978-0-9576880-0-1Google Scholar