Implementations of methods of singulating a plurality of die included in a substrate may include forming a plurality of die on a first side of a substrate, forming a backside metal layer on a second side of a substrate, applying a photoresist layer over the backside metal layer, patterning the photoresist layer along a die street of the substrate, and etching through the backside metal layer located in the die street of the substrate. The substrate may be exposed through the etch. The method may also include singulating the plurality of die included in the substrate through removing a substrate material in the die street.

A semiconductor device assembly including a substrate, a semiconductor device, a stiffener member, and mold compound. The stiffener member is tuned, or configured, to reduce and/or control the shape of warpage of the semiconductor device assembly at an elevated temperature. The stiffener member may be placed on the substrate, on the semiconductor device, and/or on the mold compound. A plurality of stiffener members may be used. The stiffener members may be positioned in a predetermined pattern on a component of the semiconductor device assembly. A stiffener member may be used so that the warpage of a first semiconductor device substantially corresponds to the warpage of a second semiconductor device at an elevated temperature. The stiffener member may be tuned by providing the member with a desired coefficient of thermal expansion (CTE). The desired CTE may be based on the individual CTEs of the components of a semiconductor device assembly.

Localized stresses can be modulated in a film deposited on a bowed semiconductor substrate by selectively and locally curing the film by ultraviolet (UV) radiation. A bowed semiconductor substrate can be asymmetrically bowed. A UV-curable film is deposited on the front side or the backside of the bowed semiconductor substrate. A mask is provided between the UV-curable film and a UV source, where openings in the mask are patterned to selectively define exposed regions and non-exposed regions of the UV-curable film. Exposed regions of the UV-curable film modulate localized stresses to mitigate bowing in the bowed semiconductor substrate.

A method of forming a semiconductor package includes attaching a first package component to a first carrier; attaching a second package component to the first carrier, the second package component laterally displaced from the first package component; attaching a third package component to the first package component, the third package component being electrically connected to the first package component; removing the first carrier from the first package component and the second package component; after removing the first carrier, performing a first circuit probe test on the second package component to obtain first test data of the second package component; and comparing the first test data of the second package component with prior data of the second package component.

Methods and systems disclosed herein can measure thin film stacks, such as film on grating and bandgap on grating in semiconductors. For example, the thin film stack may be a 1D film stack, a 2D film on grating, or a 3D film on grating. One or more effective medium dispersion models are created for the film stack. Each effective medium dispersion model can substitute for one or more layers. A thickness of one or more layers can be determined using the effective medium dispersion based scatterometry model. In an instance, three effective medium dispersion based scatterometry models are developed and used to determine thickness of three layers in a film stack.

To facilitate evaluation of a predicted process shape in process recipe development using machine learning, a process recipe search apparatus that searches for an etching recipe that is a parameter of a plasma processing apparatus set so as to etch a sample into a desired shape displays, on a display device, the predicted process shape of the sample by a candidate etching recipe predicted by using a machine leaning model, by highlighting a difference between the predicted process shape and a target shape.

A method of controlling gate formation of a semiconductor device includes acquiring a correlation between gate critical dimensions (CDs) and etching recipes for forming gate trenches; measuring a gate CD on a target wafer; determining an etching recipe based on the correction and the measured gate CD; and performing an etching process on the target wafer to form a gate trench with the determined etching recipe.

A method and device for automatic film expansion and a storage medium are provided. The method includes the following. Perform overall stretching on an expanded film. An interval between each two adjacent LED wafers on the expanded film is monitored in real time. When an interval between two adjacent LED wafers on the expanded film is greater than or equal to a preset target interval, stop performing overall stretching, and search the expanded film for a local region where an absolute difference between an interval between two adjacent LED wafers and the preset target interval is greater than a preset error threshold. When the local region exists on the expanded film, perform local stretching on the local region until an absolute difference between an interval between each two adjacent LED wafers in the local region and the preset target interval is less than or equal to the preset error threshold.

A semiconductor device has a first build-up interconnect structure formed over a substrate. The first build-up interconnect structure includes an insulating layer and conductive layer formed over the insulating layer. A vertical interconnect structure and semiconductor die are disposed over the first build-up interconnect structure. The semiconductor die, first build-up interconnect structure, and substrate are disposed over a carrier. An encapsulant is deposited over the semiconductor die, first build-up interconnect structure, and substrate. A second build-up interconnect structure is formed over the encapsulant. The second build-up interconnect structure electrically connects to the first build-up interconnect structure through the vertical interconnect structure. The substrate provides structural support and prevents warpage during formation of the first and second build-up interconnect structures. The substrate is removed after forming the second build-up interconnect structure. A portion of the insulating layer is removed exposing the conductive layer for electrical interconnect with subsequently stacked semiconductor devices.

A method for controlling a substrate temperature in a substrate processing system includes determining a temperature difference between the substrate temperature before the substrate is loaded onto a substrate support device and a desired temperature for the substrate support device and, during a first period, controlling a thermal control element to adjust the temperature of the substrate support device to a temperature value based on the temperature difference. The temperature value is not equal to the desired temperature for the substrate support device. The method further includes loading the substrate onto the substrate support device after the first period begins and before the temperature of the substrate support device returns to the desired temperature and, during a second period that follows the first period, controlling the temperature of the substrate support device to the desired temperature for the substrate support device.