A method for depth controlled ion milling, the method may include (a) ion milling a calibrated area and a target area; wherein the ion milling comprises exposing an interior of the calibrated area to provide an exposed interior of the calibrated area; wherein the target area comprises a buried region of interest that is positioned at a certain depth; wherein the calibrated area comprises a certain layer that is positioned at the certain depth; wherein the certain layer is visually distinguishable from another layer of the calibrated area that is precedes the certain layer; (ii) monitoring a progress of the milling by viewing the exposed interior of the calibrated area; and (iii) controlling of the ion milling based on an outcome of the monitoring.

To expose a desired feature, focused ion beam milling of thin slices from a cross section alternate with forming a scanning electron image of each newly exposed cross section. Milling is stopped when automatic analysis of an electron beam image of the newly exposed cross section shows that a pre-determined criterion is met.

A charged particle beam drawing apparatus has a drawing unit including a charged particle source, a deflector and a stage on which a target object is placed, to perform drawing with a charged particle beam on a plurality of drawing regions on the target object, and a calculator to calculate a drawing progress ratio on the target object using a ratio of a drawn area of the drawing regions to a total area of the drawing regions.

Methods and systems for direct atomic layer etching and deposition on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform atomic layer etch and atomic layer deposition, expressing pattern with selected 3D-structure. Reducing the number of process steps in patterned atomic layer etch and deposition reduces manufacturing cycle time and increases yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding columns, and support superior, highly-configurable process execution and control.

An object of the invention is to provide an ion beam device that can measure structures existing at different positions in a thickness direction of a sample. The ion beam device according to the invention irradiates a sample with an ion beam obtained by ionizing elements contained in a gas. After obtaining a first observation image of a first shape of a first region using a first ion beam, the ion beam device processes a hole in a second region of the sample using a second ion beam, and uses the first ion beam on the processed hole to obtain a second observation image of a second shape of the second region. By comparing the first observation image and the second observation image, a relative positional relation between the first shape and the second shape is obtained (refer to FIG. 7C).

A method for measuring conductance of a material real-time during etching/milling includes providing a fixture having a socket for receiving the material. The socket is attached to a printed circuit board (PCB) mounted on one side of a plate that has at least one opening for providing ion beam access to the material sample. Conductive probes extend from the other side of the PCB to contact and span a target area of the material. A measurement circuit in electrical communication with the probes measures the voltage produced when a current is applied across the material sample to measure changes in electrical properties of the sample over time.

A method for using differential imaging for applications involving TEM samples by allowing operators to take multiple images during a procedure involving a focused ion beam procedure and overlaying the multiple images to create a differential image that clearly shows the differences between milling steps. The methods also involve generating real-time images of the area being milled and using the overlays of the differential images to show small changes in each image, and thus highlight the ion beam milling location. The methods also involve automating the process of creating differential images and using them to automatically mill subsequent slices.

Methods, devices and systems for targeted, maskless modification of material on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform direct and knock-on ion implantation, producing patterned material modifications with selected chemical and 3D-structural profiles. The number of required process steps is reduced, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding individual columns, and support superior, highly-configurable process execution and control. Targeted implantation can be used to prepare the substrate for patterned blanket etch; patterned ALD can be used to prepare the substrate for patterned blanket deposition; neither process requiring photomasks or resist. Arrays of highly configurable beam columns can also be used to perform both positive and negative tone lithography in a single pass.

Methods, devices and systems for targeted, maskless modification of material on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform direct and knock-on ion implantation, producing patterned material modifications with selected chemical and 3D-structural profiles. The number of required process steps is reduced, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding individual columns, and support superior, highly-configurable process execution and control. Targeted implantation can be used to prepare the substrate for patterned blanket etch; patterned ALD can be used to prepare the substrate for patterned blanket deposition; neither process requiring photomasks or resist. Arrays of highly configurable beam columns can also be used to perform both positive and negative tone lithography in a single pass.

A method is provided of reducing the thickness of a region of a target sample. Reference data is obtained that is representative of x-rays generated by a particle beam being directed upon part of a reference sample under a first set of beam conditions. Under a second set of beam conditions the particle beam is directed upon the region of the target sample. The resultant x-rays are monitored as monitored data. Output data are then calculated based upon the reference and the monitored data. Material is then removed from the region, so as to reduce its thickness, in accordance with the output data.