LabAdviser/Technology Research

khara@dtu.dk
flje@dtu.dk

X-ray imaging is a widely used non-invasive imaging technique, with applications in fields such as materials science, medicine or even food quality control, where the ability to detect foreign objects can be critical. X-rays have the ability to transmit through many materials with ab- sorption rates dependent on the material density, which is used to create traditional absorption x-ray images. The ability to transmit through materials is, however, a fundamental problem for any application that requires focusing of the x-rays, since the x-rays will transmit through traditional optical lenses, without any significant refraction. Focusing of x-rays is currently done by consecutive stacking of beryllium lenses, in what is known as a compound lens, but as the x-ray sources have improved over time, the inherent refractive grain structure in the beryllium lenses have become a source of degradation of the coherence of the beam.

reet@dtu.dk

Christoffer Emil Kurt Tost Jensen s152358

The purpose of the project is to investigate sputter deposition of materials under varying conditions. It was investigated how the different parameters of Physical Vapor Deposition affects the rate and quality of the deposition. This was investigated using series of experiments designed to create a surface response model for each of the materials tested. This project will also cover what methods are ideal to use for measuring the thickness of a deposition.

taran@danchip.dtu.dk

Teitur Hansen s173963
Nataniel Andresas Olden-Jørgensen s163936

The purpose of the project is optimize the lithography process on Si/SiO2 wafers to obtain straight sidewalls for dry plasma etching. In the project we experience adhesion problems and undercut of the resist at the interface to the sample. Several tests were performed in order to overcome this problem.

mdyma@danchip.dtu.dk
tanamp@dtu.dk

Christoffer E. K. T. Jensen s152358
Rikke Bagge s151728

The purpose of the project is develop an optimized recipe for deposition of aluminium nitride (AlN) in the PEALD at Danchip. TMA and NH3 plasma have been used as precursors. A good quality AlN film should have a decent deposition rate, a high uniformity, a low roughness, a low amount of particles and a small amount of impurities (especially of oxygen and carbon). The deposited AlN layers have been characterized using a particle scanner, ellipsometry, AFM, SEM and XPS. AlN has been deposited on wafers, and the best recipe have been chosen for deposition on samples with high aspect ratio trenches. To limit the amount of depositions the design of experiment (DOE) software JMP has been used to select a number of different recipe parameters. JMP has also been used to evaluate the results.

Kristine Børsting s153299

In this 3-weeks course, the student will be working on the micro-fabrication of a Silicon/Gold grating for X-Ray optics. The fabrication of these devices require the usage of standard UV lithography combine with DRIE of silicon and metal thermal evaporation. The optimized DRIE Bosch process creates a fluorocarbon (FC) layer deposited homogeneously along the sidewall of the trench. While the depth of the trench increases with the dry etch number of cycles, an FC layer is accumulating at the top of the trench. This protrusion allows for shadow masking the sidewalls during thermal evaporation of gold, in order to deposit a seed layer at the bottom of the trench allowing for subsequent metallization by electroplating. The student will be designing a simple mask using the software CleWin. The mask will be pattern on a UV resist (5214E) using the Maskless aligner available at DTU Danchip. They will also calculate how deep the trench should be to get a minimum absorption of 92% of the intensity of the X-Ray energy.

Mathias Hoeg Boisen s164000

Asger Steen Nielsen s150369

Kitty Steenberg s141812
Mette Bybjerg Brock s134252

William Band Lomholt s4269

Emil Ludvigsen s134254

DRIE etching of deep structures in silicon samples results in rough sidewalls with scallops that for many applications are very undesirable. It has been shown that scallops can be removed by use of hydrogen annealing as the surface mobility of the silicon atoms then enhances. In this project silicon samples with DRIE etched micro trenches have then been annealed in the ATV Furnace and the Black Magic PECVD. The annealing has been done at high temperatures and both at atmospheric pressure and vacuum. Prior to the annealing some of the sample have been RCA cleaned. To evaluate the effect of the annealing the samples have been inspected using SEM.