Specific Process Knowledge/Lithography/Aligners/Aligner: Maskless 01 processing

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Process Parameters

Exposure dose

The exposure dose needed in the Aligner: Maskless 01 seems to follow the dose needed to process the same substrate in KS Aligner. As doses get higher, there is a tendency for the dose needed in the Aligner: Maskless 01 to exceed the dose needed in KS Aligner.

Defocus

The optimal defocus setting is probable a function of the resist thickness, but for 1.5µm resist, a defocus of -4 seems to be optimal.

Substrate positionning

During load, the machine will focus on the surface of the sample. Then, using the pneumatic focusing mechanism, it will detect the edges of the sample (dependent on the substrate template used) in order to determine the center of the sample. The following results rapport findings using the "4 inch wafer" template on a standard 100mm Si substrate.

Substrate centering

During the substrate detection, the sample is scanned along the X- and Y-axes, as well as diagonally. From these measurements, the diameter of the substrate is calculated, as well as the stage position matching the center of the substrate. This stage position will be the default origin for the subsequent exposure.
Unfortunately, the centering does not compensate for major or minor flats. The center position will therefor typically be displaced several mm from the center of the substrate along the Y-axis due to the major flat, and possibly also shifted due to any minor flats. These shifts have successfully been compensated during file conversion, in order to give a centering accuracy of ±200µm.

Flat alignment

At the end of the substrate detection, the sample is scanned twice along the flat, in order to determine the substrate rotation. This angle will be presented in the exposure panel along with the option to expose the design rotated in order to compensate for this angle, i.e. aligned to the flat.
The flat alignment accuracy has been measured to be 0±0.1° quite consistently. Out of a total of 13 exposures, only two were misaligned by more than 0.1°

Alignment

The alignment accuracy of the Aligner: Maskless 01 is a combination of the position accuracy of the stage, the accuracy of the alignment mark detection, and the accuracy of the pattern already on the wafer (first print).
By measuring the stitching accuracy between two layers printed on the same substrate (without unloading the substrate), we can assess the stage accuracy. By aligning to a pattern previously exposed by the Aligner: Maskless 01, we can assess the mark detection accuracy. And finally, by aligning to a pattern exposed on a mask aligner, we can assess the mask-less aligner's ability to compensate for any scaling and orthogonality errors between the two machines.

The results reported here use printed verniers to assess the misalignment along the two axes at different points on the wafer using an optical microscope. Two different designs were used; a ±5µm vernier and a ±1µm vernier. Both consist of a scale of 5µm lines with 10µm pitch, and a vernier scale to enable subdivision of the 5µm or 1µm scale into tenths, i.e. 0.5µm or 0.1µm. During inspection, observation of the symmetry of neighboring lines enables the observer to read the shifts with ±0.25µm or ±0.05µm accuracy.
The measurements are used to calculate the misalignment of the second layer with respect to the first print: The misplacement [µm] is the amount by which the design is shifted in X and Y; the rotation [ppm] is the angle by which the image is rotated; and the run-out [ppm] is the amount of gain in the image. The unit of ppm (parts per million) is used as the rotation and run-out are generally small. A rotation of 1ppm corresponds to an angle of 0.2" (arcseconds) or a shift of 100nm across an entire 4" wafer, while a run-out of 1ppm corresponds to a shift of 50nm at the edge of a 4" wafer compared to the center.
The deviations (±) given for the results here are calculated as half the range of measurements. If the range is small, the measurement uncertainty is used in stead.
The samples used for these tests are 100mm Si wafers coated with a 1.5µm layer of the positive tone resist AZ 5214E.

Stitching

In the stitching test, the design consists of ±5µm and ±1µm verniers along the X and Y axis placed in a 3 by 3 matrix covering a 60mm by 60mm area centered on the wafer. The sample is loaded, and the first layer (the linear scales) is printed. Without unloading, the second layer (the vernier scales) is printed on top of the first, and then the sample is developed.

The results in the table below show that the errors are at or below the measurement uncertainty for the stitching tests using no flat alignment. In other words, the stage is accurate to within 100nm.
When flat alignment is used, a rotation error of ~1.5ppm appears, along with a ~0.3µm misalignment and a +6ppm scaling of the Y axis. This is the level of accuracy we can expect when the rotation compensation is applied, i.e. when aligning to a previously printed layer.

Shift median [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
No flat alignment

(two samples)

X -0.03±0.05 0.01±0.05 1.00±2.33 0.00±1.18
Y -0.05±0.05 -0.07±0.05 0.42±2.33 0.00±1.18
With flat alignment X 0.00±0.05 0.05±0.05 -0.67±2.33 -1.67±1.18
Y -0.25±0.05 -0.29±0.05 6.33±2.33 -1.38±1.18

Overlay

In the overlay test, two alignment accuracies are assessed: The machine-to-self overlay accuracy (MLA-MLA), and the machine-to-machine (MA6-MLA) overlay accuracy. Because alignment is possible using two marks or four marks, both are tested in each case.

In the MLA-MLA overlay test, the design is the same as for stitching; ±5µm and ±1µm verniers along the X and Y axis placed in a 3 by 3 matrix covering a 60mm by 60mm area centered on the wafer. The sample is loaded, and the first layer (the linear scales) is printed. The sample is unloaded and developed. The second layer (the vernier scales) is aligned to marks contained in the first layer, and then the sample is developed again. The alignment marks used for 2 mark alignment are placed 60mm apart on the X axis, while the marks used for 4 mark alignment are placed at the corners of a 60mm by 30mm rectangle.

MLA-MLA Scaling [ppm] Shearing [mRad] Shift median [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
2 alignment marks

(three samples)

X NA NA -2.08±0.25 -2.07±0.25 -2.28±11.7 1.02±1.67
Y NA -0.33±0.18 -0.34±0.20 1.22±2.33 -0.46±5.89
4 alignment marks

(three samples)

X 1±2 0.002±0.001 -2.08±0.25 -2.08±0.25 -3.78±11.7 0.56±1.53
Y -12±1 -0.22±0.15 -0.21±0.05 6.44±2.33 -0.93±5.89
2 alignment marks

shifted +2µm in X

X NA NA -0.25±0.15 -0.26±0.11 -1.33±2.33 5.28±1.67
Y NA -0.30±0.25 -0.28±0.18 -1.33±2.33 3.89±1.25


In the MA6-MLA overlay test, a mask from an existing design (GreenBelt METAL v2, dark field) is reused to print the first layer using the Aligner: MA6-2, and the sample is developed. The second layer is aligned and printed in Aligner: Maskless 01, using a design containing four sets of vernier scales located at the corners of a ~90mm by ~3mm rectangle. For 2 mark alignment, the original alignment marks at X±~43mm are used. Since only two alignment marks exist in the original design, four corners (positioned in a ~60mm by ~60mm square pattern) are used for manual alignment in the 4 mark test. Using corners rather than crosses reduces the accuracy of the alignment, as the positions of corners are subject to shifts due to bias in the first print lithography.

MA6-MLA Scaling [ppm] Shearing [mRad] Shift median [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
2 alignment marks X NA NA -1.5±0.75 -1.5±0.25 20.8±11.7 2.78±3.93
Y NA 0.00±0.25 0.00±0.25 NA NA
4 alignment marks X -8 0.005 -1.75±0.63 -1.69±0.25 18.7±11.7 12.5±3.93
Y 13 0.25±0.63 0.19±0.25 NA NA