FR2641622A1 - Photolithography mask - Google Patents

Abstract

The present invention relates to a photolithography mask 10 consisting of a transparent plate in which ribs or grooves 11 are formed, no absorbent material being provided in these grooves or on these ribs. This mask makes it possible to form, in a layer of resin 22 formed on a substrate 20, exposed strips 25 facing the discontinuities when light is projected on the sample through the mask.

Description

PgOTOLITYOGRAPHTU GSQUE
The present invention relates to photolithography masks, in particular masks which can be used in the contact photolithography process.

 Photolithography is a process which consists in forming a layer of a photosensitive product, hereinafter called resin, on top of a layer to be etched, having the property of being selectively attackable by an etching product using locations where it was lit (positive resin) or where it was not lit (negative resin). The openings formed in the resin layer are then used to etch the underlying layer or layers.

 In mask photolithography processes, the image of a mask conforming to the pattern to be engraved is formed on the resin to expose it. The image of the mask can be projected onto the resin or the mask can be in contact with the resin layer.

 FIGS. 1A and 1B very schematically represent conventional mask structures. These masks consist of a substrate 1 transparent to active radiation and of zones 2 opaque to this radiation. In the case of FIG. 1A, the opaque zones have been shown in relief with respect to the substrate 1. Most commonly, these opaque zones are made of chromium and the transparent substrate is quartz. In the case of FIG. 1B, the opaque substance 2 has been represented, arranged in grooves previously formed in the substrate 1.

 When using such masks, we inevitably come up against a lower resolution limit linked to the wavelength of sunshine and to the numerical aperture of the projection lens, in the case of a projection system, and the wavelength and the value of the thickness of the resin layer, in the case of contact systems. We therefore seek to use the shortest possible active wavelengths. Currently, for example, we commonly use wavelengths located in the ultraviolet range of the order of a few hundred nanometers, for example the line. at 248 na supplied by an excimer laser. We arrive for this wavelength at a resolution limit of around 500 nm for projection techniques and around 200 nm for contact techniques.

 If we still want to reduce this resolution, we are currently having to abandon photolithography techniques by mask and to resort to photolithography techniques without mask by directly using a projecti on of electron beams deviated appropriately on the layer to be exposed. This technique achieves resolutions of the order of 100 nm but is extremely complex and requires very high investments.

 Thus, an object of the present invention is to provide a photolithophy mask making it possible to descend to a resolution of the same order of magnitude as that which can currently be achieved by direct electronic insolation.

 This object is achieved by providing a photolithography mask consisting of a plate transparent to active radiation, this plate comprising thickness discontinuities at the locations where it is desired to form an image formed of lines on a resin.

 Thus, the present invention makes it possible to delimit in a resin strips of given width and variable spacing, said width depending on the wavelength of the exposure beam and on the profile of the thickness discontinuities.

The present invention will be explained below in more detail with reference to the accompanying figures, among which
FIGS. 1A and 1B represent conventional photolithophy masks
FIG. 2 represents a mask according to the present invention associated with a photolithographic structure
FIG. 3 schematically represents a structure obtained using a mask according to the present invention;
FIGS. 4A-4B, 5A-5B, 6A-6B show, for various dimensions of mask patterns according to the present invention, the structures capable of being obtained.

 Figure 2 shows a mask according to the present invention. This mask comprises a plate 10 transparent to active radiation, on one face of which grooves or ribs are formed 11. It should be emphasized that the difference between the mask 10 and that shown in FIG. 1B is that no substance opaque to the light is arranged in the grooves. The mask 10 is made of a single transparent material having only discontinuities of thickness.

 In FIG. 2, the mask 10 is shown arranged opposite a sample on which it is desired to carry out a photolithography operation and comprising a substrate 20, a layer to be etched 21, and a layer of photosensitive resin 22. Experience shows that if the sample is exposed through the mask li placed in contact with the sample, it forms on the resin layer 22 of the unlit strips 25 opposite the discontinuities of thickness of the mask. This effect, probably linked to optical scattering and / or diffraction phenomena, depends practically, under given contact conditions, only on the wavelength used and on the profile of the sides of the grooves 11.

In practice, it has been found that for irradiation at a wavelength of the order of 200 nm, the width of an opaque band was approximately 100 nm, that is to say substantially half of the wave length.

 It is therefore possible, after exposure, and once the conventional photolithography steps have been implemented, to obtain a structure such as that shown in FIG. 3 in which only ribs 26 of layer 21 remain opposite the opaque bands formed in the resin layer 22. The ribs 26 (or vice versa the grooves if a negative resin had been chosen) have a constant width and their spacing is adjusted by the difference between the thickness discontinuities formed in the mask 10.

 Those skilled in the art will note that it is possible to combine on a single mask a structure according to the present invention and a structure such as that of FIG. 1B by coating the grooves 11 which one does not want to fill with material opaque according to the invention with a protective layer, then by depositing in other grooves an opaque substance 2 as in FIG. 1B then by eliminating the protective layer in the grooves 11. It is thus possible, on the one hand, the variable width patterns conventionally obtained with conventional masks, on the other hand, bands of constant width obtained with the mask according to the present invention.

 The main advantage of the mask according to the present invention is that these bands, for a given wavelength have a width much less than that which can be obtained with a conventional mask. As indicated previously, the optimal resolution limit in the case of a contact mask with opaque zones is of the order of 200 nm for a wavelength of 200 nn while it is only 100 to 150 nm by the method according to the present invention for the same wavelength, which represents a gain of a factor of the order of 2.

 FIGS. 4B to 63 illustrate the patterns that can be obtained with masks 4A to 6A according to the present invention as a function of the distance between neighboring discontinuities (for example the two sides of a groove), in the case where the illumination wavelength is approximately 200 nm. For a groove width of 200 nm illustrated in FIG. 4A, the effect of the two adjacent discontinuities merges and one obtains an opaque band of width substantially greater than that of the groove, for example of the order of 300 nm (FIG. 4B ). For a groove with a width of 300 nm (FIG. 5A), one begins to resolve the two opaque spots but a semi-illuminated area remains between them (FIG. 5B) which does not make it possible to obtain clearly separated bands at the end of the photolithography process. As illustrated in FIG. 6A, for a groove width of 500 nm, we obtain engraved bands, illustrated in FIG. 6B, having a width of the order of 100 to 150 nm separated by a distance of approximately 35C nm .

 Thus, the present invention is particularly suitable for forming, in the context of the production of an integrated circuit, relief bands of constant and very small width, and of variable spacing.

Claims (6)

REFENDICATl0'sS  1. Photolithography mask consisting of a plate (10) transparent to active radiation, characterized in that said plate comprises thickness discontinuities (11)  2. Mask according to claim 1, characterized in that said plate is provided with grooves.  3. Mask according to claim 1, characterized in that said plate is provided with ribs.  4. Mask according to claim 2, characterized in that some selected grooves are filled with an opaque material with active rayon.  5. Mask according to claim 1, characterized in that the thickness discontinuities are separated by a distance substantially equal to twice the wavelength of the active radiation.  6. Mask according to claim 1, characterized in that the transparent plate is a quartz plate.