A chemical turnstile is a device for transporting small, well-characterized doses of atoms from one location to another. A working turnstile has yet to be built, despite the numerous technological applications available for such a device. The key difficulty in manufacturing a chemical turnstile is finding a medium which will trap and transport atoms. Here we propose that ferroelastic twin walls are suitable for this role. Previous work shows that twin walls can act as two-dimensional trapping planes within which atomic transport is fast. We report simulations showing that a stress-induced reorientation of a twin wall can occur. This behavior is ideal for chemical turnstile applications.

Topics
Phase transitions, Static properties, Superconductivity, Free energy, Crystalline solids, Ferroelasticity, X-ray diffraction, Microprobe, Nanotechnology
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© 2005 American Institute of Physics.
2005
American Institute of Physics
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