Patent application number | Description | Published |
20140116873 | METHOD FOR CREATING S/TEM SAMPLE AND SAMPLE STRUCTURE - An improved method and apparatus for S/TEM sample preparation and analysis. Preferred embodiments of the present invention provide improved methods for TEM sample creation, especially for small geometry (<100 nm thick) TEM lamellae. A novel sample structure and a novel use of a milling pattern allow the creation of S/TEM samples as thin as 50 nm without significant bowing or warping. Preferred embodiments of the present invention provide methods to partially or fully automate TEM sample creation, to make the process of creating and analyzing TEM samples less labor intensive, and to increase throughput and reproducibility of TEM analysis. | 05-01-2014 |
20140190934 | METHOD FOR PREPARING SAMPLES FOR IMAGING - A method and apparatus is provided for preparing samples for observation in a charged particle beam system in a manner that reduces or prevents artifacts. Material is deposited onto the sample using charged particle beam deposition just before or during the final milling, which results in an artifact-free surface. Embodiments are useful for preparing cross sections for SEM observation of samples having layers of materials of different hardnesses. Embodiments are useful for preparation of thin TEM samples. | 07-10-2014 |
20140217283 | TEM Sample Preparation - An improved method of preparing ultra-thin TEM samples that combines backside thinning with an additional cleaning step to remove surface defects on the FIB-facing substrate surface. This additional step results in the creation of a cleaned, uniform “hardmask” that controls the ultimate results of the sample thinning, and allows for reliable and robust preparation of samples having thicknesses down to the 10 nm range. | 08-07-2014 |
20150053548 | TEM SAMPLE PREPARATION - An improved method of preparing ultra-thin TEM samples that combines backside thinning with an additional cleaning step to remove surface defects on the FIB-facing substrate surface. This additional step results in the creation of a cleaned, uniform “hardmask” that controls the ultimate results of the sample thinning, and allows for reliable and robust preparation of samples having thicknesses down to the 10 nm range. | 02-26-2015 |
20150102009 | METHOD FOR PREPARING THIN SAMPLES FOR TEM IMAGING - A method and apparatus for preparing thin TEM samples in a manner that reduces or prevents bending and curtaining is realized. Embodiments of the present invention deposit material onto the face of a TEM sample during the process of preparing the sample. In some embodiments, the material can be deposited on a sample face that has already been thinned before the opposite face is thinned, which can serve to reinforce the structural integrity of the sample and refill areas that have been over-thinned due to a curtaining phenomena. In other embodiments, material can also be deposited onto the face being milled, which can serve to reduce or eliminate curtaining on the sample face. | 04-16-2015 |
20150179402 | METHOD FOR PREPARING SAMPLES FOR IMAGING - A method and apparatus is provided for preparing samples for observation in a charged particle beam system in a manner that reduces or prevents artifacts. Material is deposited onto the sample using charged particle beam deposition just before or during the final milling, which results in an artifact-free surface. Embodiments are useful for preparing cross sections for SEM observation of samples having layers of materials of different hardnesses. Embodiments are useful for preparation of thin TEM samples. | 06-25-2015 |
20150243477 | Bulk Deposition for Tilted Mill Protection - To reduce artifacts in a surface exposed by a focused ion beam for viewing, a trench is milled next to the region of interest, and the trench is filled to create a bulkhead. The ion beam is directed through the bulkhead to expose a portion of the region of interest for viewing. The trench is filled, for example, by charged particle beam-induced deposition. The trench is typically milled and filled from the top down, and then the ion beam is angled with respect to the sample surface to expose the region of interest. | 08-27-2015 |
20150243478 | High Aspect Ratio Structure Analysis - Curtaining artifacts on high aspect ratio features are reduced by reducing the distance between a protective layer and feature of interest. For example, the ion beam can mill at an angle to the work piece surface to create a sloped surface. A protective layer is deposited onto the sloped surface, and the ion beam mills through the protective layer to expose the feature of interest for analysis. The sloped mill positions the protective layer close to the feature of interest to reduce curtaining. | 08-27-2015 |