KR19990065974A - Wavelength Separation Method of Exposure Equipment - Google Patents

Abstract

The wavelength separation method of the exposure apparatus according to the present invention comprises the steps of injecting a light source having a mixture of several wavelengths to the light scattering element, and the light incident on the light scattering element is a different light path for each wavelength And the separation step and the step of injecting the light separated by the wavelength into the alignment light source through the adjustment of the light scattering element, thereby reducing the noise effect caused by the light of different wavelengths, thereby improving the alignment mark detection signal. By changing the lower thin film structure, it is possible to secure the alignment accuracy and eliminate the need for multiple alignment light sources.

Description

Wavelength Separation Method of Exposure Equipment

The present invention relates to a wavelength separation method of an exposure apparatus. In particular, since one wavelength is used instead of several wavelengths, noise effects due to light of different wavelengths can be reduced, thereby improving alignment mark detection signals and changing a lower thin film structure. The present invention relates to a wavelength separation method of an exposure apparatus capable of securing alignment accuracy and eliminating the need for multiple alignment light sources.

The photocoated emulsion wafer is placed on a machine that adjusts the position of the wafer and mask. The machine is capable of adjusting in multiple directions and can hold the wafer by a vacuum chuck. The carrier containing the glass mask is then placed in a mask holder on the wafer. The mask holder is capable of only jet movement. Above the device is a high magnification microscope and a movable ultraviolet source. A glass mask is a commonly used high resolution photographic glass plate that includes a circuit pattern placed on a wafer. The circuits look like integrated circuits or transistors, and the same circuits are repeated at regular intervals. In addition, in order to make transistors or integrated circuits, several different kinds of mask patterns must be used. Therefore, in order to accurately match the focus every time, these circuit shapes are made of a special shape of a certain shape at a certain position and used for aiming / aligning.

The alignment system and algorithm of the exposure equipment is different for each company. The general alignment method forms an alignment reference mark in a patterning step of a lower process, and when the next upper pattern forming process is performed, an upper light source is formed by analyzing a signal returned by illuminating the alignment light source on the alignment mark.

In the prior art, as shown in FIGS. 1 and 2, the alignment mark 1 is formed during the lower process, and the wafer reference when the lower process is progressed by analyzing the signal returned from the alignment light source when forming the upper process pattern. Get location information. At this time, the main parameters for the alignment light source for the exact position detection of the alignment mark with reference to Figure 3 as follows. The center wavelength of the alignment light sources 11 and 12, the wavelength region of the alignment light sources 11 and 12, the light intensity of the alignment light sources 11 and 12, and the light quality of other light sources. In the figure, reference numeral 2 denotes an alignment mark position detection signal, 11 denotes a halogen lamp, 12 denotes a helium-neon laser, 13 and 14 denote a reflection mirror, and 15 and 16 denote an optical path for an alignment light source. Represent each.

In general, when different types and thick thin films are stacked after the lower process, light interference between the thin films occurs. Since the interference phenomenon can be changed by adjusting the wavelength related to the refractive index, the conventional technology has a problem in that the thin film laminated structure causing random extinction interference is fixed by fixing the wavelength region of the light source.

Accordingly, an object of the present invention is to conceive in view of the above problems, it is possible to reduce the noise effect due to the light of different wavelengths because it uses one wavelength without using multiple wavelengths, improve the alignment mark detection signal, It is possible to secure alignment accuracy by changing a thin film structure, and to provide a wavelength separation method of an exposure apparatus that does not require multiple alignment light sources.

1 is a diagram showing an alignment mark on a wafer according to a general technique.

Fig. 2 is a signal diagram showing an alignment mark position detection signal on a wafer according to a general technique.

3 is a block diagram showing a wavelength separation operation of an exposure apparatus according to the prior art.

4 is a block diagram showing a wavelength separation operation of the exposure apparatus according to the present invention.

(Explanation of symbols for the main parts of the drawing)

21; Light source 22; Light scattering element

23; Angle adjusting motor 24; Reflection mirror

25; Light path for alignment light source

The object of the present invention is to inject a light source having a mixture of several wavelengths into a light scattering element, and to separate the light incident on the light scattering element with a different light propagation path for each wavelength. And by integrating the wavelength-separated light into the alignment light source through adjustment of the light scattering device.

Hereinafter, the wavelength separation method of the exposure apparatus according to the present invention will be described according to the embodiment shown in the accompanying drawings.

4 is a block diagram showing the wavelength separation operation of the exposure apparatus according to the present invention. As shown in the drawing, the wavelength separation method of the exposure apparatus according to the present invention includes a light source 21 in which components of various wavelengths are mixed. Incident light into the light dispersing element 22, and separating the light incident on the light dispersing element 22 having a different light traveling path for each wavelength, and splitting the light having the wavelength separated therefrom. Through the adjustment of the oxygen atom 22, the process proceeds in the order of incidence into the light path 25 for alignment light sources.

The light scattering element 22 is adjusted by an angle adjusting motor 23 connected to the light scattering element.

The present invention employs a light scattering element 22 such as a prism in the prior art so that the wavelength can be selected. In other words, when light having a plurality of wavelengths mixed is incident on a prism, which is a dispersion element 22, and separated into respective wavelengths, light of a single wavelength output is selected and used as an alignment light source. In the figure, reference numeral 24 denotes a reflection mirror.

The wavelength separation method which is the core of the present invention is as follows.

The light source 21 in which various wavelength line segments are mixed is incident on the light scattering element 22. In this case, both the halogen lamp and the laser may be used as the light source 21 in which various wavelength components are mixed. The light incident on the light scattering element 22 changes in the path of the light traveling according to the incident angle. That is, the wavelengths are separated by having different optical paths for each wavelength. Then, the wavelength separated light is incident on the alignment light source path 25. At this time, the selection of the incident wavelength is made through the adjustment of the angle adjusting motor 23 of the light scattering element 22. That is, in the case of the prism, the incident wavelength is selected by adjusting the angle. As described above, higher alignment accuracy can be obtained by determining alignment signal characteristics and alignment accuracy according to the wavelength change using light having independent wavelengths.

As described above, the wavelength separation method of the exposure apparatus according to the present invention includes the steps of injecting a light source having a mixture of components of various wavelengths into the light scattering element, and the light incident on the light scattering element for each wavelength. Since the separation proceeds in the order of having different light traveling paths and incidence of the light having the wavelength separated by incident light into the alignment light source through the adjustment of the light scattering device, it is possible to reduce the noise effect caused by the light of different wavelengths. The detection signal is improved, and the lower thin film structure is changed to secure the alignment accuracy, and there is an effect of eliminating the need for multiple alignment light sources.

Claims (1)

Injecting a light source having a mixture of wavelengths into a light scattering element, separating the light incident on the light scattering element with a different light propagation path for each wavelength, and separating the wavelengths And a step of injecting light into the alignment light source through adjustment of the light scattering device.