Ultrathin IBAD MgO films for epitaxial growth on amorphous substrates and sub-50 nm membranes

Abstract: A fabrication process has been developed for high energy ion beam assisted deposition (IBAD) biaxial texturing of ultrathin (∼1 nm) MgO films, using a high ion-to-atom ratio and post-deposition annealing instead of a homoepitaxial MgO layer. These films serve as the seed layer for epitaxial growth of materials on amorphous substrates such as electron/X-ray transparent membranes or nanocalorimetry devices. Stress measurements and atomic force microscopy of the MgO films reveal decreased stress and surface rough… Show more

“…4(f)]. At a high IAR of 0.79, the 5 nm thick IBAD-MgO film exhibited a strong in-plane texture of 6°, consistent with the previous work studied by Siming Wang et al 17) They fabricated an ultra-thin (∼1 nm) IBAD-MgO film using a very high IAR of 0.9. In terms of low IARs (0.2, 0.34, and 0.47), the biaxial texture was maintained in the IBAD-MgO layer when the thickness increased up to 50-60 nm, which was the highest value explored.…”

“…Due to the strong binding force between the MgO atoms and the amorphous Y 2 O 3 layer, the MgO films exhibit a layer-by-layer growth mode at the initial stage. We speculate that it is the reason why ultra-thin (∼1 nm) IBAD-MgO films exhibiting excellent biaxial texture were obtained by S. Wang et al 17) When the Y 2 O 3 layer is completely covered by MgO atoms, the transition from the layer-by-layer to island-based growth of IBAD-MgO occurs, which would make the surface rougher. It is reported that the roughness of IBAD-MgO increases during film thickening.…”

“…Meanwhile, it is worth noting that, by using a high IAR of 0.8-0.9, ultra-thin (1-2 nm) IBAD-MgO films exhibiting excellent biaxial texture can be achieved. 17) Therefore, the underlying nucleation mechanism of MgO thin films via IBAD is still under debate. It is believed that a more detailed description of the texture evolution of MgO with different IARs would provide important insight into the understanding of the IBAD-MgO growth mechanism.…”

Biaxial texture establishment and evolution in IBAD-MgO films under different ion-to-atom ratios

“…4(f)]. At a high IAR of 0.79, the 5 nm thick IBAD-MgO film exhibited a strong in-plane texture of 6°, consistent with the previous work studied by Siming Wang et al 17) They fabricated an ultra-thin (∼1 nm) IBAD-MgO film using a very high IAR of 0.9. In terms of low IARs (0.2, 0.34, and 0.47), the biaxial texture was maintained in the IBAD-MgO layer when the thickness increased up to 50-60 nm, which was the highest value explored.…”

“…Due to the strong binding force between the MgO atoms and the amorphous Y 2 O 3 layer, the MgO films exhibit a layer-by-layer growth mode at the initial stage. We speculate that it is the reason why ultra-thin (∼1 nm) IBAD-MgO films exhibiting excellent biaxial texture were obtained by S. Wang et al 17) When the Y 2 O 3 layer is completely covered by MgO atoms, the transition from the layer-by-layer to island-based growth of IBAD-MgO occurs, which would make the surface rougher. It is reported that the roughness of IBAD-MgO increases during film thickening.…”

“…Meanwhile, it is worth noting that, by using a high IAR of 0.8-0.9, ultra-thin (1-2 nm) IBAD-MgO films exhibiting excellent biaxial texture can be achieved. 17) Therefore, the underlying nucleation mechanism of MgO thin films via IBAD is still under debate. It is believed that a more detailed description of the texture evolution of MgO with different IARs would provide important insight into the understanding of the IBAD-MgO growth mechanism.…”

Biaxial texture establishment and evolution in IBAD-MgO films under different ion-to-atom ratios

“…First, Hastelloy shows an excellent corrosion resistance than pure metal foils under diverse electrolyte conditions such as acids, bases, and seawater atmosphere. Besides, Hastelloy C-276 shows high thermal resistance to form crystalline phases under a high-temperature process, indicating that Hastelloy is an appropriate candidate to fabricate films at high temperature. − In addition, Hastelloy has an advantage in growing various crystalline thin films by using lattice matching by inserting well-known stable template layers such as Al 2 O 3 , Y 2 O 3 , and MgO. − Accordingly, Hastelloy has been widely used for the growth of crystalline thin films in various fields, including superconductors, , ferroelectrics, optoelectronics, and solar cells; , that is, the crystalline photoelectrode can also be sufficiently fabricated on Hastelloy substrates through template engineering.…”

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