Abstract: A method and apparatus for growing an oxide layer within a feature of a substrate is described herein. The method is suitable for use in semiconductor manufacturing. The oxide layer is formed by exposing a substrate to both a high pressure oxidant exposure and a lower pressure oxygen containing plasma exposure. The high pressure oxidant exposure is performed at a pressure of greater than 10 Torr, while the lower pressure oxygen containing plasma exposure is performed at a pressure of less than about 10 Torr. The features are high-aspect ratio trenches or holes within a stack of silicon oxide and silicon nitride layers.

Abstract: An ultrasound system includes an ultrasound scanner configured to transmit ultrasound at a patient anatomy and generate ultrasound data as part of an ultrasound examination. The ultrasound system also includes an ultrasound machine configured to generate, based on the ultrasound data, an ultrasound image. The ultrasound system also includes a processor system implemented to determine features selected from the group consisting of regional features, patient features, clinician features, and ultrasound examination feature. The processor system is implemented to generate, based on the ultrasound image and the features, a patient recommendation.

Abstract: An ultrasound system includes an ultrasound scanner configured to transmit ultrasound at a patient anatomy and generate ultrasound data as part of an ultrasound examination. The ultrasound system also includes an ultrasound machine configured to generate, based on the ultrasound data, an ultrasound image. The ultrasound system also includes a processor system implemented to determine features selected from the group consisting of regional features, patient features, clinician features, and ultrasound examination feature. The processor system is implemented to generate, based on the ultrasound image and the features, a patient recommendation.

Abstract: An ultrasound system includes an ultrasound scanner, a patient-worn registration system configured in at least a one-way communication with an interventional instrument, and a processor system. The processor system is configured to determine, based on the ultrasound data and positional data of the ultrasound scanner, a first location of the patient anatomy relative to the patient-worn registration system, determine, based on the at least a one-way communication, a second location of the interventional instrument relative to the patient-worn registration system; and determine, based on the first location and the second location, a third location of the interventional instrument relative to the patient anatomy. The processor system is configured to display a depiction of the patient anatomy based on the ultrasound data and a visual representation of the interventional instrument at the third location on a display device.

Abstract: An electrochromic (EC) device includes a substrate and a plurality of layers formed on the substrate. The plurality of layers includes an active layer that is lithiated for changing a tint of the EC device. The active layer is lithiated using a deposition process that uses one or more lithium (Li) targets. The deposition process provides, on no more than 1.5% of manufactured EC devices, a Li tungsten-oxide deposit area on the substrate that is over-concentrated with Li relative to a surrounding area on the substrate. In some aspects, the EC device may be a component of an EC system that further includes a power supply electrically connected to the EC device and configured to provide a voltage to the EC device for controlling a tint of the EC device.

Abstract: Described herein is a method of depositing a conformal, optically transparent coating onto a surface of one or more internal components that are enclosed within an assembled device including an optical encoder using a non-line-of-sight deposition process without altering a structure of the assembled device or impacting functionality of the assembled device. Also described is an assembled device including an optical encoder, where one or more internal components enclosed within the optical encoder and a coating deposited onto a surface of the internal components, where the coating is a conformal, optically transparent coating that is resistant to corrosion by at least one of fluorine-, chlorine-, sulfur-, hydrogen-, bromine-, or nitrogen-based acids and that does not negatively impact functionality of the internal components.

Abstract: A method includes performing a dry etch process to remove a portion of a first layer disposed on a second layer of a stack of alternating layers. The first layer includes a first material and the second layer includes a second material different from the first material, and the dry etch process forms a passivation layer including a byproduct on surfaces of the second material. A amount of first material of the portion of the first layer remains after performing the dry etch process, The method further includes introducing a halide gas to enhance the passivation layer on the surfaces of the second material.

Abstract: Systems and methods for automated reporting in Point-of-Care ultrasound (POCUS) workflows are described. In some embodiments, an ultrasound reporting system includes a memory configured to maintain a mapping of system events to worksheet answers. A processor system is coupled to the memory and is configured to implement a reporting application at least partially in hardware. The reporting application is implemented to determine, during an ultrasound examination, an occurrence of a system event of the system events. The reporting application is also implemented to determine, based on the mapping, a worksheet answer of the worksheet answers that is mapped to the system event. The reporting application is also implemented to populate, during the ultrasound examination and responsive to the determination of the occurrence of the system event, a medical worksheet with the worksheet answer.

Abstract: This disclosure provides systems, devices, methods, and apparatus, for coordinating scanners in an ultrasound cart. An ultrasound system can include an ultrasound cart having a scanner holder configured to hold ultrasound scanners, a display device configured to display a visual representation of the scanner holder, and at least one of the ultrasound scanners. The visual representation can be implemented to identify locations of the ultrasound scanners on the scanner holder. The ultrasound scanners can be configured to indicate, while being held in the scanner holder, that one ultrasound scanner of the ultrasound scanners is to be selected for an ultrasound examination. The ultrasound scanner can also be configured to implement a first ultrasound imaging mode when a display device is attached to the ultrasound cart, and a second ultrasound imaging mode and not the first ultrasound imaging mode when the display device is removed from the ultrasound cart.

Abstract: A method includes providing, within an etch chamber, a base structure including a target layer disposed on a substrate, and an etch mask disposed on the target layer, dry etching, within the etch chamber, the target layer using thionyl chloride to obtain a processed base structure, and after forming the plurality of features. The processed base structure includes a plurality of features and a plurality of openings defined by the etch mask. The method further includes removing the processed base structure from the etch chamber. In some embodiments, the target layer includes carbon. In some embodiments, the dry etching is performed at a sub-zero degree temperature.

Abstract: Described herein is a method of depositing a conformal, optically transparent coating onto a surface of one or more internal components that are enclosed within an assembled device using a non-line-of-sight deposition process without altering a structure of the assembled device or impacting functionality of the assembled device. Also described is an assembled device including one or more internal components enclosed within the assembled device and a coating deposited onto a surface of the internal components enclosed within the assembled device, where the coating is a conformal, optically transparent coating that is resistant to corrosion by at least one of fluorine-, chlorine-, sulfur-, hydrogen-, bromine-, or nitrogen-based acids and that does not negatively impact functionality of the internal components.

Abstract: Certain embodiments are directed to a method, system, or apparatus, such as a medical imaging device. The method can include retrieving data from a worksheet or form repository server. The data can include one or more fields of a customized worksheet or form. The one or more fields can be based on at least one of an identification of a user, a location of the medical imaging device, or a medical department using the medical imaging device. The method can also include recreating the customized worksheet or form at the medical imaging device based on the received data, and displaying the recreated customized worksheet or form on a graphical user interface connected to the medical imaging device. In addition, the method can include producing a medical image via the medical imaging device, and automatically forwarding the customized worksheet or form and the medical image to a billable workflow or an educational workflow.

Abstract: Described herein is a chamber component including a metal layer comprising nickel and a barrier layer of nickel oxide over the metal layer. The barrier layer of nickel oxide may be formed by ozone treating the chamber component with air, nitrogen or argon O2, O3 at a temperature from about 25° C. to about 350° C.

Abstract: A method and apparatus for growing an oxide layer within a feature of a substrate is described herein. The method is suitable for use in semiconductor manufacturing. The oxide layer is formed by exposing a substrate to both a high pressure oxidant exposure and a lower pressure oxygen containing plasma exposure. The high pressure oxidant exposure is performed at a pressure of greater than 10 Torr, while the lower pressure oxygen containing plasma exposure is performed at a pressure of less than about 10 Torr. The features are high-aspect ratio trenches or holes within a stack of silicon oxide and silicon nitride layers.

Abstract: An ultrasound probe and a ultrasound system are disclosed. In some embodiments, the ultrasound system includes a bite block configured to, during a transesophageal insertion of the probe cable starting from the distal end, guard the probe cable from a bite and prevent anteflexion and retroflexion movement of the transducer until a predetermined length of the probe cable is inserted.

Abstract: An ultrasound probe and an ultrasound system are disclosed. In some embodiments, the ultrasound probe includes a probe body having a user interface with controls and a mode selector. In some embodiments, when the mode selector is in a first setting, the controls are configured to control a probe transducer, and when the mode selector is in a second setting, the controls are configured to control the ultrasound machine via a probe transceiver.

Abstract: Described herein is a method of depositing a conformal, optically transparent coating onto a surface of one or more internal components that are enclosed within an assembled device using a non-line-of-sight deposition process without altering a structure of the assembled device or impacting functionality of the assembled device. Also described is an assembled device including one or more internal components enclosed within the assembled device and a coating deposited onto a surface of the internal components enclosed within the assembled device, where the coating is a conformal, optically transparent coating that is resistant to corrosion by at least one of fluorine-, chlorine-, sulfur-, hydrogen-, bromine-, or nitrogen-based acids and that does not negatively impact functionality of the internal components.

Abstract: Certain embodiments are directed to a method, system, or apparatus, such as a medical imaging device. The method can include retrieving data from a worksheet or form repository server. The data can include one or more fields of a customized worksheet or form. The one or more fields can be based on at least one of an identification of a user, a location of the medical imaging device, or a medical department using the medical imaging device. The method can also include recreating the customized worksheet or form at the medical imaging device based on the received data, and displaying the recreated customized worksheet or form on a graphical user interface connected to the medical imaging device. In addition, the method can include producing a medical image via the medical imaging device, and automatically forwarding the customized worksheet or form and the medical image to a billable workflow or an educational workflow.

Abstract: An illumination device and methods are provided herein for avoiding over-current and over-power conditions in one or more power converters included within the illumination device. The illumination device may include at least a plurality of light emitting diode (LED) chains, a driver circuit, at least one power converter, and a control circuit. In some embodiments, the control circuit may be generally configured for determining a maximum safe current level and/or a maximum safe power level attributed to the power converter(s) at a present operating temperature, and for adjusting respective drive currents supplied to the plurality of LED chains by the driver circuit, so as not to exceed the maximum safe current level or the maximum safe power level at the present operating temperature. In some embodiments, a temperature sensor may be included within the illumination device for measuring the operating temperature presently associated with the power converter(s).