Materials Science and Engineering

Biography

Biography: Osman Adiguzel

Abstract

Some materials take place in class of smart materials with adaptive properties and   stimulus response to the external changes. Shape memory alloys take place in this group, due to the shape reversibility and capacity of responding to changes in the environment. These alloys have a peculiar property called shape memory effect. Shape memory effect is initiated by cooling and stressing treatments in material in bulk level and performed thermally on heating and cooling after first treatments. Therefore, this behavior is called thermoelasticity. These alloys exhibit another property called superelasticity, which is performed by stressing and releasing at a constant temperature in the parent austenite phase region. Shape memory effect is result of successive thermal and stress induced martensitic transformations. Thermal induced martensitic transformation occurs on cooling along with lattice twinning, with which ordered parent phase structures turn into twinned martensite structures, and twinned structures turn into detwinned martensite structures by means of strain induced martensitic transformation with deformation in martensitic state. Thermal  transformations occur with cooperative movement of atoms by means of lattice invariant shears in <110>-type directions on a {110} - type plane of austenite matrix.  

Superelasticity is performed in only mechanical manner. These alloys can be deformed in parent phase region just over austenite finish temperature and recover the original shape on releasing the applied stress. Superelasticity is also result of stress induced martensitic transformation which occurs only  by  mechanical stress at a constant temperature. With this stress, parent austenite phase structures turn into the fully detwinned martensite. Superelasticity exhibits normal elastic material behaviour, but it is performed in non-linear way, unlike normal elastic materials. Loading and unloading paths are different, and hysteresis loop refers to the energy dissipation.

Copper based alloys exhibit this property in metastable b - phase region, which  has bcc-based structures at high temperature parent phase field. Lattice invariant shear and twinning is not uniform in copper alloys and they give rise to the formation of unusual layered complex structures, like 3R, 9R or 18R structures depending on tha stacking sequences, with lattice twinning.

In the present contribution, x-ray diffraction and transmission electron microscopy studies were carried out on two copper based CuZnAl and CuAlMn alloys. X-ray diffraction profiles and electron diffraction patterns  exhibit super lattice reflections inherited from parent phase due to the displacive character of martensitic transformation. Specimens of these alloys aged at room temperature in martensitic condition, and a series of x-ray diffractions were taken duration aging at room temperature. Reached results show that diffraction angles and peak intensities change with aging time at room temperature, and this result leads to the rearrangement of atoms in diffusive manner.