Science Advances

Supplementary Materials

The PDF file includes:

  • Note S1. Theoretical analysis of phase transition time for thawing.
  • Note S2. Fabrication of transformative electronics with flexible, stretchable electrode arrays.
  • Note S3. Fabrication of transformative electronics integrated with a stretchable PCB.
  • Note S4. Fabrication of neural probe with variable stiffness.
  • Fig. S1. Design and application of a transformative electronics that can convert between an EMG sensor and a handheld touch sensor.
  • Fig. S2. Design of testbed transformative platforms for mechanical studies.
  • Fig. S3. Characterization of the degree of supercooling.
  • Fig. S4. Thermal characterization of gallium-based transformative platform using IR camera during thawing process and freezing process.
  • Fig. S5. Design of transformative electronics that can convert between a rigid tabletop clock and a stretchable wearable sensor with characterization.
  • Fig. S6. Mechanical simulation of bending stiffness of the transformative electronics that appeared in Fig. 3E.
  • Fig. S7. Fabrication process of a transformative pressure sensor.
  • Fig. S8. Transformative resistive pressure sensor built with a gallium frame.
  • Fig. S9. Response time of the pressure sensor in rigid and soft mode.
  • Fig. S10. Design and implementation of TES optical neural probe for behavioral experiments with wireless control.
  • Legends for movies S1 to S4

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Other Supplementary Material for this manuscript includes the following:

  • Movie S1 (.mp4 format). Movie of a transformative electronics transforming between a rigid tabletop clock and a wearable sensor.
  • Movie S2 (.mp4 format). Movie of a transformative pressure sensor with variable deformability.
  • Movie S3 (.mp4 format). Movie of a transformative pressure sensor: Application demonstration in rigid and soft modes.
  • Movie S4 (.mp4 format). Movie of a transformative neural probe penetrating a mouse brain in rigid mode.

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