Embodiments of the present disclosure relate to the field of semiconductors, and provide a process recipe, a method and a system for generating same, and a semiconductor manufacturing method. The method for generating a diffraction-based process recipe includes: providing a basic process recipe, the basic process recipe is used to form an initial alignment pattern; and performing a feedback correction step for at least one time to adjust the basic process recipe and obtain an actual process recipe, which each time includes: obtaining a first pattern and a second pattern based on the basic process recipe prior to a current feedback correction step, the first pattern is the initial alignment pattern that is developed, the second pattern is the initial alignment pattern that is etched; and adjusting the basic process recipe prior to the current feedback correction step based on a difference between the first pattern and the second pattern.

The present application discloses a dose mapper method, which includes: step 1: collecting critical dimension fingerprint of each tool and each mask and storing the critical dimension fingerprint in a database; step 2: before exposing a wafer, pre-selecting the tool and the mask to be used, selecting the corresponding critical dimension fingerprint from the database and combining the corresponding critical dimension fingerprint to form total critical dimension fingerprint; step 3: obtaining dose mapper data for exposure of the wafer according to the total critical dimension fingerprint; step 4: exposing the wafer, and correcting the exposure of the wafer according to the dose mapper data in an exposure process. The present application can quickly and easily generate a dose mapper data file, especially when there is a new tool or mask to be expanded, thus improving the efficiency of generating the dose mapper data file and improving the production capacity.

An exposure method includes reading data representing a relationship between a first parameter relating to an energy ratio between energy of first pulsed laser light having a first wavelength and energy of second pulsed laser light having a second wavelength longer than the first wavelength and a second parameter relating to a sidewall angle of a resist film that is the angle of a sidewall produced when the resist film is exposed to the first pulsed laser light and the second pulsed laser light, and determining a target value of the first parameter based on the data and a target value of the second parameter; and exposing the resist film to the first pulsed laser light and the second pulsed laser light by controlling a narrowed-line gas laser apparatus to output the first pulsed laser light and the second pulsed laser light based on the target value of the first parameter.

A control method for a line narrowed gas laser apparatus is a control method for a line narrowed gas laser apparatus configured to emit a pulse laser beam including a first wavelength component and a second wavelength component. The apparatus includes a laser chamber including a pair of electrodes, an optical resonator including an adjustment mechanism configured to adjust a parameter of an energy ratio of the first and second wavelength components, and a processor in which relation data indicating a relation of the parameter of the energy ratio with a control parameter of the adjustment mechanism is stored. The control method includes receiving a command value of the parameter of the energy ratio from an external device, and acquiring, based on the relation data, a value of the control parameter corresponding to the command value and controlling the adjustment mechanism based on the value of the control parameter.

A method for determining a metric of a feature on a substrate obtained by a semiconductor manufacturing process involving a lithographic process, the method including: obtaining an image of at least part of the substrate, wherein the image includes at least the feature; determining a contour of the feature from the image; determining a plurality of segments of the contour; determining respective weights for each of the plurality of segments; determining, for each of the segments, an image-related metric; and determining the metric of the feature in dependence on the weights and the calculated image-related metric of each of the segments.

An exposure system according to an aspect of the present disclosure includes a laser apparatus emitting a pulse laser beam, an illumination optical system guiding the pulse laser beam to a reticle, a reticle stage moving the reticle, and a processor controlling emission of the pulse laser beam and movement of the reticle. The exposure system performs scanning exposure of a semiconductor substrate by irradiating the reticle with the pulse laser beam. The reticle has first and second regions. The processor instructs the laser apparatus about, based on proximity effect characteristics corresponding to the first and second regions, a value of a control parameter of the pulse laser beam corresponding to each region so that the laser apparatus emits the pulse laser beam with which a difference of the proximity effect characteristic of each region from a reference proximity effect characteristic is in an allowable range.

An exposure system according to an aspect of the present disclosure includes a laser apparatus that outputs pulsed laser light, an illuminating optical system that guides the pulsed laser light to a reticle, a reticle stage, and a processor that controls the output of the pulsed laser light from the laser apparatus and the movement of the reticle performed by the reticle stage. The reticle has a first region where a first pattern is disposed and a second region where a second pattern is disposed, and the first and second regions are each a region continuous in a scan width direction perpendicular to a scan direction of the pulsed laser light, with the first and second regions arranged side by side in the scan direction. The processor controls the laser apparatus to output the pulsed laser light according to each of the first and second regions by changing the values of control parameters of the pulsed laser light in accordance with each of the first and second regions.

A method for determining a metric of a feature on a substrate obtained by a semiconductor manufacturing process involving a lithographic process, the method including: obtaining an image of at least part of the substrate, wherein the image includes at least the feature; determining a contour of the feature from the image; determining a plurality of segments of the contour; determining respective weights for each of the plurality of segments; determining, for each of the segments, an image-related metric; and determining the metric of the feature in dependence on the weights and the calculated image-related metric of each of the segments.

The present application relates to a dispatch method for a production line in a semiconductor process, a storage medium and a semiconductor device. The dispatch method for a production line in a semiconductor process can acquire an overlay error reference curve of a product lot to be exposed in equipment and set an overlay error range according to the overlay error reference curve. At the end of exposure, an overlay error for the product lot to be exposed can be acquired, and it can be determined whether the overlay error falls into the overlay error range. If the overlay error for the product lot to be exposed does not fall into the overlay error range, the product lot to be exposed can be continuously machined by this equipment.

A method for determining a best focus and a best dose in the disclosure includes selecting a selection pattern from first and second shot regions of a wafer for split, measuring a critical dimension (CD) value of the selection pattern, thereby deriving a measurement CD value, calculating an effective CD value of the selection pattern for each of the first and second shot regions using the measurement CD value, calculating an upper-limit CD value and a lower-limit CD value of the selection pattern using the effective CD value of the selection pattern, calculating a process window area for the first shot region and a process window area for the second shot region using the upper-limit CD value and the lower-limit CD value of the selection pattern, and comparing the process window area for the first shot region and the process window area for the second shot region with each other.