“
“Background Most optoelectronic devices based in quantum
dots (QDs) such as optical amplifiers [1], infrared detectors Epigenetics inhibitor [2], or lasers [3] require stacking of multiple QDs layers to enhance properties as the number of photons emitted or absorbed per unit area. For small spacer layers, QDs tend to align vertically because of the strain fields caused by the buried dots [4, 5]. These strain fields have a strong effect in the size and shape of the QDs and consequently, in the optoelectronic properties of the corresponding devices [6–11]. The vertical distribution of the QDs has a direct effect in its electronic structure due to a possible CP868596 electron tunneling between layers [12], and it has also been found to influence optical properties such as the photoluminescence emission of the structure [13]. Because of this, understanding the 3D distribution of stacked QDs is essential to understand and optimize the functional properties
of a wide range of devices. Although various techniques have been used to assess the vertical distribution of QDs [14–16], one of the most powerful techniques for this purpose is transmission electron microscopy (TEM) because it gives direct evidence of the location of the QDs. However, the vertical alignment of the stacking of QDs is often analyzed by TEM from 2D projections of the volume of the sample in one or several directions GSI-IX clinical trial [17, 18], losing 3D information and therefore, making the complete correlation with the optical characteristics unfeasible. To solve this problem, electron tomography is the most appropriate technique. An accurate 3D reconstruction in electron tomography needs the accomplishment of some requirements, the most important one being that BCKDHA the input 2D images must be the true projections
of the original 3D object [19]. This condition can be met by using high-angle annular dark field (HAADF) scanning transmission electron microscopy (STEM) images for the tilting series, given that the diffraction effects present in conventional bright field TEM images are minimized. On the other hand and regarding the specimen, it is required that the electron beam crosses a constant thickness of the electron-transparent foil when traveling through the sample during the tilting series. This is not accomplished by the thin foils prepared by the conventional method of specimen preparation, and only cylindrical or conical-shaped specimens with the symmetry axis parallel to the tilting axis would meet this requirement. The fabrication of these specimens in the form of needles has been recently accomplished with the use of a dual beam scanning electron microscopy-focused ion beam instrument (FIB), and it has been applied to atom probe analyses [20], electron tomography studies [21], and 3D-STEM observations [22].