| OMNIPROBE, INC. Patent applications |
| Patent application number | Title | Published |
|---|
| 20120025075 | METHOD AND APPARATUS FOR ACQUIRING SIMULTANEOUS AND OVERLAPPING OPTICAL AND CHARGED PARTICLE BEAM IMAGES - This disclosure relates to a method and apparatus for producing multiple pixel-by-pixel simultaneous and overlapping images of a sample in a microscope with multiple imaging beams. A scanning electron microscope, a focused ion-beam microscope, or a microscope having both beams, also has an optical microscope. A region of interest on a sample is scanned by both charged-particle and optical beams, either by moving the sample beneath the beams by use of a mechanical stage, or by synchronized scanning of the stationary sample by the imaging beams, or by independently scanning the sample with the imaging beams and recording imaging signals so as to form pixel-by-pixel simultaneous and overlapping images. | 02-02-2012 |
| 20110204226 | APPARATUS FOR STEM SAMPLE INSPECTION IN A CHARGED PARTICLE BEAM INSTRUMENT - An apparatus for in-situ sample examination in a dual-beam FIB includes a cassette for holding probe tips inside the FIB, where the FIB has an X-Y plane and a port for a nano-manipulator probe shaft, and where the probe shaft is further capable of releasably holding a probe tip. The cassette has a base and at least one probe-tip station connected to the base. The probe-tip station has a slot for receiving a probe tip, where the probe-tip slot has an angle with respect to the base substantially equal to the angle of the port for the nano-manipulator probe shaft relative to the X-Y plane of the FIB. The cassette has a clamp with springy fingers located in the slot for receiving and releasably holding the probe tip. The apparatus is adapted to in-situ STEM examination of samples. | 08-25-2011 |
| 20110031397 | METHOD FOR STEM SAMPLE INSPECTION IN A CHARGED PARTICLE BEAM INSTRUMENT - A method for sample examination in a dual-beam FIB calculates a first angle as a function of second, third and fourth angles defined by the geometry of the FIB and the tilt of the specimen stage. A fifth angle is calculated as a function of the stated angles, where the fifth angle is the angle between the long axis of an excised sample and the projection of the axis of the probe shaft onto the X-Y plane. The specimen stage is rotated by the calculated fifth angle, followed by attachment to the probe tip and lift-out. The sample may then be positioned perpendicular to the axis of the FIB electron beam for STEM analysis by rotation of the probe shaft through the first angle. | 02-10-2011 |
| 20110031396 | METHOD FOR STEM SAMPLE INSPECTION IN A CHARGED PARTICLE BEAM INSTRUMENT - A method for sample examination in a dual-beam FIB calculates a first angle as a function of second, third and fourth angles defined by the geometry of the FIB and the tilt of the specimen stage. A fifth angle is calculated as a function of the stated angles, where the fifth angle is the angle between the long axis of an excised sample and the projection of the axis of the probe shaft onto the X-Y plane. The specimen stage is rotated by the calculated fifth angle, followed by attachment to the probe tip and lift-out. The sample may then be positioned perpendicular to the axis of the FIB electron beam for STEM analysis by rotation of the probe shaft through the first angle. | 02-10-2011 |
| 20110017927 | METHOD AND APPARATUS FOR THE MONITORING OF SAMPLE MILLING IN A CHARGED PARTICLE INSTRUMENT - An apparatus for monitoring sample milling in a charged-particle instrument has a variable-tilt specimen holder ( | 01-27-2011 |
| 20110017922 | VARIABLE-TILT TEM SPECIMEN HOLDER FOR CHARGED-PARTICLE BEAM INSTRUMENTS - A variable-tilt specimen holder for a charged particle instrument having a tilt stage, where the tilt stage has a maximum range of tilt, a sample plate affixed to the tilt stage, and an ion-beam column having an ion-beam column axis. The variable-tilt specimen holder has a base for mounting to the sample plate, so that the base is substantially parallel to the tilt stage. Bearing blocks on the base rotatably support a pivot plate that has slots for holding TEM specimens or TEM grids holding specimens. The pivot plate is rotatable so that the TEM specimens held therein can be aligned with the axis of the ion beam column for thinning of the specimen. The pivot plate has a range of relation sufficient to move the preferred axis of thinning of the specimen from a first position where the tilt stage is placed at its maximum range of tilt and the angle between the preferred axis of thinning of the specimen and the axis of the ion beam column is greater than zero to a second position where the preferred axis for thinning of the specimen is substantially parallel to the ion-beam column axis. Clamps are provided to securely hold the TEM specimens or TEM grids. | 01-27-2011 |
| 20100202042 | MULTIPLE MAGNIFICATION OPTICAL SYSTEM WITH SINGLE OBJECTIVE LENS - A multiple magnification optical system ( | 08-12-2010 |
| 20100200546 | METHOD OF ETCHING MATERIALS WITH ELECTRON BEAM AND LASER ENERGY - We disclose a method of electron-beam induced of etching the surface of a specimen in a charged-particle beam instrument, where the charged-particle beam instrument has first and second laser beams, an electron beam, and a gas-injection system for applying etchant gas to the surface. Etching is accomplished by applying a photolytic pulse from the first laser to the surface; applying a pyrolytic pulse from the second laser to the surface; and, applying an etchant gas to the surface at least during the pyrolytic pulse. Two or more alternating pyrolytic laser pulses and photolytic laser pulses may be applied to the surface. The stage supporting the specimen may be tilted relative to the axis of the electron beam before applying the electron beam to the surface of the specimen. The electron beam is applied to the surface of the specimen during the time the etchant gas is present at the surface. | 08-12-2010 |
| 20100068408 | METHODS FOR ELECTRON-BEAM INDUCED DEPOSITION OF MATERIAL INSIDE ENERGETIC-BEAM MICROSCOPES - We disclose method for materials deposition on a surface inside an energetic-beam instrument, where the energetic beam instrument is provided with a laser beam, an electron beam, and a source of precursor gas. The electron beam is focused on the surface, and the laser beam is focused to a focal point that is at a distance above the surface of about 5 microns to one mm, preferably from 5 to 50 microns. The focal point of the laser beam will thus be within the stream of precursor gas injected at the sample surface, so that the laser beam will facilitate reactions in this gas cloud with less heating of the surface. A second laser may be used for cleaning the surface. | 03-18-2010 |
| 20100051802 | SINGLE-CHANNEL OPTICAL PROCESSING SYSTEM FOR ENERGETIC-BEAM MICROSCOPES - A single-channel optical processing system for an energetic-beam instrument has separate sources for processing radiation and illumination radiation. The processing radiation and the illumination radiation are combined in a single optical path and directed to a sample surface inside the energetic-beam instrument through a self-focusing rod lens. The self-focusing rod lens thus has a working distance from the sample surface that will not interfere with typical arrangements of ion beams and electron beams in such instruments. A combination of polarizers and beam splitters allows separation of the combined incident radiation and the combined radiation reflected from the sample surface and returned through the same optical channel, so that the reflected radiation may be directed to an optical detector, such as a camera or spectrometer. In other embodiments, additional illumination of the sample surface is provided at an angle to the central axis of the self-focusing rod lens. | 03-04-2010 |
| 20100025580 | GRID HOLDER FOR STEM ANALYSIS IN A CHARGED PARTICLE INSTRUMENT - A grid holder for STEM analysis in a charged-particle instrument has a base jaw and a pivoting jaw. Both jaws have a substantially congruent inclined portion. The base jaw has a flat portion for mounting the holder on the sample carousel of a charged-particle instrument, such as a dual beam FIB. The inclined portion of the jaws is inclined to the flat portion of the holder at an angle A approximately equal to the difference between 90 degrees and the angle between the electron beam and the ion beam in the charged-particle instrument. The inclined portion of the jaws has a pocket for receiving and holding a sample grid. When a sample is mounted on the grid and the grid is held by the grid holder, the sample will be correctly oriented for ion-beam thinning when the sample carousel is horizontal. The thinned sample may then be placed perpendicular to the electron beam for STEM analysis by tilting the sample carousel by the same angle A. | 02-04-2010 |
| 20090320624 | Method for Preparing Specimens for Atom Probe Analysis and Specimen Assemblies Made Thereby - A method for making a specimen assembly for atom probe analysis in an energetic-beam instrument includes milling a post near a region of interest in a sample in the energetic-beam instrument, so that the post has a free end. The probe tip of a nano-manipulator probe shaft is attached to the free end of the post and the post is cut free from the sample to form a rough specimen, so that the region of interest in the rough specimen is exposed at approximately the location where the post is cut from the sample. A specimen assembly form is provided having an open area inside its perimeter. The probe shaft bearing the specimen is joined to the specimen assembly form, so that the region of interest in the rough specimen is located in the open area. Thereafter, the probe shaft can be cut off outside the perimeter of the specimen assembly form, and the specimen conveniently held and sharpened for atom probe analysis. Specimen assembly forms made by the method are also disclosed. | 12-31-2009 |
| 20090294690 | METHOD OF FORMING TEM SAMPLE HOLDER - A TEM sample holder is formed from at least one nano-manipulator probe tip and a TEM sample holder pre-form. The probe tip is permanently attached to the TEM sample-holder pre-form to create a TEM sample holder before attachment of a sample to the point of the probe tip inside a FIB. In the preferred embodiment the probe tip is attached to the TEM sample holder pre-form by applying pressure to the pre-form and the probe tip, so as to cause plastic flow of the pre-form material about the probe tip. The TEM sample holder may have smaller dimensions than the TEM sample holder pre-form; in this case the TEM sample holder is cut from the larger TEM sample holder pre-form, preferably in the same operation as attaching the probe tip. | 12-03-2009 |
| 20090015274 | METHOD FOR AUTOMATED STRESS TESTING OF FLIP-CHIP PACKAGES - Methods for testing flip-chip packages includes aligning a microscope and a test engine. The package under test is placed between the microscope and the test engine, and an acoustic transducer is attached to the package under test. The test engine delivers an impact to the package under test on the side of the package opposite its ball-grid array. Acoustic information and image information from the package under test is recorded. In alternate embodiments, a sequence of packages may be automatically tested. | 01-15-2009 |
| 20080258056 | METHOD FOR STEM SAMPLE INSPECTION IN A CHARGED PARTICLE BEAM INSTRUMENT - A method for sample examination in a dual-beam FIB calculates a first angle as a function of second, third and fourth angles defined by the geometry of the FIB and the tilt of the specimen stage. A fifth angle is calculated as a function of the stated angles, where the fifth angle is the angle between the long axis of an excised sample and the projection of the axis of the probe shaft onto the X-Y plane. The specimen stage is rotated by the calculated fifth angle, followed by attachment to the probe tip and lift-out. The sample may then be positioned perpendicular to the axis of the FIB electron beam for STEM analysis by rotation of the probe shaft through the first angle. | 10-23-2008 |
