Difference between revisions of "Electronic skin: architecture and components"

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'''Basic Experimental Details'''
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'''Main Experimental Details and Observations'''
  
  
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As substrate the authors use a poly-dimethyl-siloxane (PDMS) membrane of 1mm thickness. The metal layers, ranging in thickness from 5nm to 500nm, were gold deposited using electron-beam evaporation. Samples were prepared both on relaxed substrates and on stretched substrates which were subsequently released.
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Using relaxed substrates did not yield consistent results; sometimes the metal films buckled, and sometimes they didn't (Fig.3). This difference is attributed to differences in the internal stresses of the film, as suggested by the different structural properties in the two cases on the nanometer scale (Fig. 4). Films that buckled are smooth on that scale whereas films that did not buckle have micro-cracks - a difference that has direct relation to electrical conductivity. 
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Using pre-stretched substrates, however, always yielded wavy films (Fig. 6).
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As substrate the authors use a poly-dimethyl-siloxane (PDMS) membrane of 1mm thickness. The metal layers, ranging in thickness from 5nm to 500nm, were gold deposited using electron-beam evaporation.
 
  
  

Revision as of 16:32, 1 November 2011

Wagner, Lacour, Jones, Hsu, Sturm, Li, Suo, Physica E 25 (2004), 326-334

Summary


Flexible electronics have a host of potential applications ranging from medicine (e.g. prosthetic skin) to flexible electronic devices. The materials traditionally used for the fabrication of circuits, such as silicon, are stiff. Flexible counterparts may be possible with the combination of an elastomer substrate on which conducting metal connections can be deposited; the system may then sustain considerable stress. The question the authors address is how subjecting a flexible substrate to strain affects the electrical properties of the deposited conductors.

Their initial approach to fabricating these systems was based on the creation of wavy metal films on elastomer substrates which could be stretched reversibly. The waviness of the films was caused by internal stresses within the metal-elastomer system, in a way that they have modelled in a previous publication [1]. Interestingly, such wavy films are not only stretchable, but they maintain their conductivity while stretched. In order to have more control over the orientation and lengthscale of the film features, and thus over the stretchability of the conducting film, the authors have also deposited metal films on stretched PDMS substrates. When the substrates are let to relax, the superimposed films buckle in a way that correlates with the initial conditions of the substrate: peaks and troughs form along the axis of initial expansion. Furthermore, the existence of a substrate on which the metal is bonded makes the films more robust to deformations.


Main Experimental Details and Observations


As substrate the authors use a poly-dimethyl-siloxane (PDMS) membrane of 1mm thickness. The metal layers, ranging in thickness from 5nm to 500nm, were gold deposited using electron-beam evaporation. Samples were prepared both on relaxed substrates and on stretched substrates which were subsequently released. Using relaxed substrates did not yield consistent results; sometimes the metal films buckled, and sometimes they didn't (Fig.3). This difference is attributed to differences in the internal stresses of the film, as suggested by the different structural properties in the two cases on the nanometer scale (Fig. 4). Films that buckled are smooth on that scale whereas films that did not buckle have micro-cracks - a difference that has direct relation to electrical conductivity.

Using pre-stretched substrates, however, always yielded wavy films (Fig. 6).







[1] S.P.Lacour, S.Wagner, Z.Huang, Z.Suo, Mater.Res.Soc.Proc. 736 (2002) D4.8.1