FR2908875A1 - Transparent flexible membrane i.e. protection film, deformation contactless measurement device for photomask cleaning and depolluting device, has isolation unit receiving and isolating reflected light beam to measure membrane displacement - Google Patents

Abstract

The device has a generating unit (3) with a laser source for generating an incident light beam (I) having a wavelength around 900 nanometer, and for obliquely directing the light beam towards a transparent flexible membrane (1). An isolation unit (5) receives and isolates the reflected light beam (4') to measure displacement of the membrane, where the light beam is reflected by the membrane. The incident light beam makes an incidence angle with a surface of the membrane, and interacts with a central zone of the membrane.

Description

2908875 1 Non-contact measuring device for the deformation of a

  The present invention relates to a device for non-contact measurement of the deformation of a membrane, and its application to a device for cleaning and decontamination of sealed non-sealed environments. Flexible membranes are used in particular in the semiconductor industry. It may be, for example, films for protecting photomasks. A photomask is equivalent to a negative in photography, that is to say that it contains on a support generally called blank a pattern intended to be reproduced on a substrate. It is used to transmit, in the chosen pattern, a light radiation which strikes a photosensitive layer on a semiconductor substrate. In the mask, active areas transmit the radiation, while inactive areas stop the radiation. Pollution in an active zone has a direct effect on the pattern printed on the substrate: the pattern is then printed with a defect, an erroneous form of engraved pattern. Pollution can also have an indirect effect on the printed image if they occur outside the active areas. The problems generated can be for example the reduction of the contrast or the reduction of the transmission of the photomask. In the semiconductor industry, it is constantly sought to reduce the size of the patterns to be printed in order to obtain ever smaller and less expensive electronic components. As the dimensions of printing patterns are reduced, pollution requirements become more and more stringent. The photomask is therefore a key element, expensive and complex that one seeks to keep clean and operational. A photomask consists of a support whose surface receives the 3o pattern to reproduce. The pattern should be protected to prevent the deposition of polluting particles. For this, at the end of its manufacturing process, the photomask is cleaned and inspected. If it is clean and flawless, the photomask is film-coated and is ready to be used, stored or transported. The protective film must protect the photomask during its lifetime. It consists of an optical membrane (multilayer surfaces) 2908875 2 having a good optical transmission and a reduced impact on the optical rays that pass through it. This protective film is deposited on the side of the active face of the photomask and is separated therefrom by a space of about 6 mm provided by an element commonly called film support. The polluting particles possibly present in the environment of the photomask will thus be deposited on the protective film instead of being deposited on the active area of the photomask. The pollutants, kept away from the active area of the photomask, are thus outside the focusing area of the light radiation when using the photomask, and therefore do not produce a printed image on the semiconductor substrates . The film does not completely protect the photomask from pollutants, but it reduces their impact on the quality of the image. The protective film is most often glued around the periphery of the active part of the mask and is spaced therefrom by the film support. The atmosphere under the film is confined, but not completely isolated from the outside atmosphere. Indeed, there is provided a small passage, for example a low conductance filter, which passes through the film support to balance as much as possible the gas pressures on both sides of the film. Thus the elements constituting the photomask, namely the blank support, the film support and the protective film, form a sealed non-sealed environment. It has recently been known that pollutants may be present under the protective film. Crystalline growth phenomena in the active zone of the photomask can be observed. This pollution has a direct effect on the quality of the patterns reproduced. Its situation under the film makes cleaning difficult. The cleaning of a photomask already provided with its film is until now long, complex and expensive. It is necessary to remove the film and then re-deposit it. This must be done by the photomask manufacturers and not by the users, which causes a loss of time as well as significant additional costs for inventory management related to a shortened life of the photomasks. Conventionally, the protective film protecting the active zone of the photomask has an approximate dimensions of 10 cm × 10 cm and a thickness of a few microns. These dimensions make this membrane extremely fragile. A simple contact by mechanical support would have the effect of damaging or destroying the protective film. Thus, the control of the deformation of this membrane can be performed only through a non-contact measurement.

To store or transport the photomasks, they are generally introduced into sealed enclosures, usually plastic. These speakers are generally not waterproof. This is why it is important to clean and clean the objects inside. For this, it is evacuated in the indoor atmosphere of these sealed enclosures 10 which can be purged by injecting a neutral gas. The advantage of this neutral gas is that it will not combine with other residual gases (degassing walls or other), polluting the atmosphere. During these cleaning and depollution steps, the gaseous pressure of the atmosphere surrounding the objects such as the photomasks is thus varied. However, the low conductance filter provided in the film support does not have sufficient conductance to ensure a natural balance of pressures on both sides of the membrane if the surrounding pressure varies too rapidly. This then results in the establishment of a differential pressure which forces the membrane 20 outwardly or inwardly of the photomask, with a significant risk of rupture of the membrane. In order to limit the pressure differences on either side of the membrane, and thus to preserve the membrane, suitable pumping and purge means have been used up to now, which slowly pump the sealed enclosure 25 and a slow introduction of the purge gases. This has the effect that the time required to perform these cleaning and depollution steps is very long. The pressure differences on both sides of the protective film are dangerous for this very fragile membrane. They can damage it or even destroy it. To preserve the protective film of the photomask, it is necessary not to exceed the limit of elastic deformation of the membrane. In commerce, there are sensors to monitor without contact the deformation or displacement of an object. A first known sensor uses ultrasound to measure the deformation or displacement of an object. The transmitter sends a wave train which will reflect on the object to be detected and then return to the source. The time taken to go back and forth makes it possible to determine the distance of the object from the source. This type of sensor can detect any type of material except objects absorbing sound waves. However, absolutely no operation is possible in vacuum. Thus ultrasonic sensors can not be used to measure the deformation of the film of a photomask during the steps when it is subjected to low pressure. In commerce, a second type of sensor for measuring deformation is available, based on laser detection. However, this type of sensor only gives a binary result on the flatness of the membrane, and does not make it possible to quantify the non-zero deformation of a membrane. The problem proposed by the present invention is to quantify without contact the deformation of a membrane subjected to a differential pressure in a low pressure atmosphere.

According to another aspect, the invention also proposes a device and a method for cleaning and depolluting objects which define a sealed non-sealed environment limited by a flexible wall, avoiding degrading the membrane while substantially reducing the duration of the cleaning and depollution process.

To achieve these and other objects, the invention provides a non-contact measuring device for the deformation of a flexible, transparent, fixed at its ends and pressure differential membrane, including means for generating a beam incident light and direct it obliquely towards the membrane, and means for receiving and isolating the light beam reflected by the membrane and for measuring the displacement thereof. This device has the effect of providing, without contact with the membrane, a reliable measurement of the deformation of the membrane even when it is in a low pressure atmosphere. What could not be done with the devices of the prior art.

In practice, it can be provided that the means for generating an incident light beam comprise a laser source, advantageously emitting radiation at a wavelength of about 900 nm. This increases the sensitivity of the device. The incident light beam is preferably directed to the zone of maximum deformation of the membrane (central zone of the membrane) precisely by the use of the laser. The accuracy of the laser is due to the spatial coherence (at every point of the beam, the phase is the same) and to the temporal coherence (conservation of the phase during a coherence period) characteristic of the laser.

The incident light beam then interacts with (is reflected by) the central zone of the membrane. The means for receiving and isolating the reflected light beam are selected with respect to the means for generating the incident light beam. In practice, the means for receiving and isolating the reflected light beam 10 may comprise an ordered array of photoelectric receivers adapted to receive the beams reflected by the different surfaces lying in the path of the incident light beam, comprising the beam reflected by the membrane, and to produce electrical signals images of the amplitude and position of the light energy reaching the matrix.

In addition, the means for receiving and isolating the reflected light beam analyze the electrical signals from the matrix, distinguish, by its relative position, the signal corresponding to the beam reflected by the membrane, and output a signal corresponding to the position of the light beam reflected by the membrane.

According to a first aspect, the measuring device according to the invention can be used to control the deformation of a protective film of a photomask in a variable pressure atmosphere. In this way, it can be ensured that the deformation is not likely to cause degradation of the film.

According to another aspect, this same measuring device according to the invention can be used to limit the pressure variations of the atmosphere surrounding a protective film photomask. By controlling the deformation of the membrane with the pressure variations that are subjected to the photomask, the risks of degradation of the membrane are limited. In another aspect, the measuring device according to the invention is used in a device for cleaning and depolluting objects such as photomasks. For this purpose there is provided a device for cleaning and depollution of a sealed non-sealed environment object limited by a flexible membrane wall, comprising: a watertight cleaning and depollution chamber provided with a transparent wall portion by which light beams interacting with the flexible membrane can enter and exit, - pumping means, - a source of purge gas, containing a purge gas or mixture of gases, - an inlet for connecting to the gas source purging the cleaning and depollution chamber, - an outlet for connecting to the pumping means the cleaning and decontamination chamber, 10 - control means for controlling the pumping means and the purge gas source, in which control means control the pumping means and / or the source of purge gas according to a signal provided by a measuring device according to the invention.

According to another aspect, the invention provides a method for cleaning and decontaminating a sealed non-sealed environment object limited by a flexible membrane wall, comprising the following steps: placing the non-confined environment object; sealed in a sealed chamber comprising means for injecting a gas or mixture of purge gas and pumping means, the deformation of the membrane is measured continuously by means of a sensor according to the invention; pumps the gas contained in the sealed enclosure and the gas contained in the interior space of the confined environment not sealed, and / or a purge gas is introduced into the sealed enclosure and into the interior space of the non-sealed confined environment object, - the pumping and / or introduction of purge gas is controlled according to the signal given by the sensor, so as to maintain the deformation of the membrane within a permissible limit of deformation.

It is understood that the time required to clean and clean a photomask depends essentially on the pumping and purging times. These times depend directly on the admitted deformation of the membrane. The lower the admitted deformation, the lower the differential pressure which is the cause on either side of the membrane, and the more the variations in the surrounding pressure must be slow. The pumping and purging times are then long. This is the solution necessarily chosen with the known devices which do not allow the control of the deformations of the membrane. Conversely, the method according to the invention makes it possible to optimize the treatment time while preserving the membrane or protective film from excessive deformation, since it is possible to accept without danger sensitive but non-destructive deformations of the membrane. which allows faster variations of the surrounding pressure. Other objects, features and advantages of the present invention will become apparent from the following description of particular embodiments, with reference to the accompanying figures, in which: FIG. 1 is a general schematic view of a measuring device according to the invention; FIG. 2 is a detailed schematic view of a use of the measuring device according to the invention; and FIG. 3 is a graph showing temporal variations in the deformation of a photomask membrane and the differential pressure across the membrane. FIG. 1, which schematically illustrates a non-contact measurement device for the deformation of a membrane 1, hereinafter referred to as measuring device according to the invention. The membrane 1 is fixed at its ends by fixing means 2. Its central portion is free. Means 3 generate an incident light beam I. The incident light beam I is directed towards the zone of maximum deformation of the membrane 1. The incident light beam I hits the membrane 1. The incident light beam I makes with the surface of the membrane 1 an angle of incidence of about 56, so that the partial reflection on the membrane 1 has an optimal light intensity. The membrane 1 has a thickness of a few microns. The incident light beam I interacts with the membrane 1 and is reflected. Due to the very small thickness of the membrane, the two reflected rays (one being the ray reflected by the upper face of the membrane and the second being the ray reflected by the lower face 1b of the membrane) are considered as a single reflected ray 4.

The reflected ray 4 strikes at Z3 means 5 for receiving and isolating the light beam 4 reflected by the membrane 1.

When the membrane 1 is not subjected to a differential pressure, it remains flat. However, when the pressure Pext applying to the upper face of the membrane 1 is different from the pressure P; nt applying to the lower face 1b of the membrane 1, the membrane 1 is deformed.

In the case where P ext is greater than Dinh the membrane 1 deforms downwards. If P; nt is greater than Pext, the membrane 1 is deformed upwards, as represented by the dashed lines in FIG. 1. In the latter case, the incident ray I interacts with the membrane 1 a little before the zone of maximum deformation. The reflected ray 4 '(shown in dashed lines in FIG. 1) will strike at Z'3 the means 5 for receiving and isolating the light beam reflected by the membrane 1. The means 5 for receiving and isolating the light beam reflected by the membrane 1 make it possible to determine the deformation of the membrane 1 as a function of the displacement of the impact zone Z3 of the reflected ray 4.

FIG. 1 illustrates that these means 5 for receiving and isolating the light beam reflected by the membrane 1 comprise a first element 5a sensitive to the light radiation and its position, and a second element 5b for analyzing the presence signals and position of light radiation. Figure 2 is a more detailed schematic view of the measuring device according to the invention, illustrating its particular use for controlling the deformation of a protective film of a photomask in a variable pressure atmosphere. A photomask 100 consists of a support 6, a film support 7 comprising a leak 7a, a protective film separated from the active zone 25 of the support 6 by means of the film support 7. In the case described on FIG. 2, the protective film of the photomask constitutes a flexible membrane such as the membrane 1 of FIG. 1. Thus, in the remainder of this description, the protective film of the photomask 100 will be designated by the expression membrane 1.

The photomask 100 constitutes a non-sealed confined environment object. The confined environment is the volume enclosed between the membrane 1, the film support 7 and the support 6. The photomask 100 is placed on a support 11 in a sealed enclosure 9 consisting of three opaque walls (the side walls and the wall 35). lower) and an upper wall provided with a transparent window or porthole 10.

The sealed enclosure 9 is connected to pumping means 12 capable of pumping the gases from the inside atmosphere of the sealed enclosure 9, and to means 13 for supplying gas. The first element 5a sensitive to the light radiation and to its position receives different reflected light beams. The second element 5b analyzes the presence and position signals provided by the first element 5a, and isolates the signals relating to the reflected ray 4 coming from the membrane 1. In practice, a structure of the first element 5a means 5 for receiving and isolating the light beam reflected by the membrane is illustrated in front view on the right side of FIG. 2. In this example the first element 5a comprises an ordered matrix of elementary photoelectric receivers such as the receivers 50a and 51a, oriented and positioned to separately receiving the light beams reflected by the different surfaces in the path of the incident light beam I. The elementary photoelectric receivers each produce an electrical signal whose amplitude is a function of the light energy that reaches it. The means 3 for generating an incident light beam generate an incident light beam I which interacts with the central zone of the membrane 1 of the photomask 100.

On its way, the incident light beam I meets the upper face 10a of the window 10, then the lower face 10b of the window 10, then the membrane 1 and finally the support 6. These faces each reflect a part of the incident light beam I. R1 beam reflected by the upper face 10a of the window 10 is struck 25 Z1 the first element 5a means 5 for receiving and isolating the light beam reflected by the membrane 1. The beam R2 reflected by the lower face 10b of the window 10 struck in Z2 the first element 5a means 5 for receiving and isolating the light beam reflected by the membrane 1.

The beam 4 reflected by the membrane 1 strikes at Z3 the first element 5a means 5 for receiving and isolating the light beam reflected by the membrane 1. The beam R4 reflected by the support 6 strikes at Z4 the first element 5a means 5 to receive and isolate the light beam reflected by the membrane 1. The ordered array of photoelectric receivers constituting the first element 5a is adapted to distinguish the impacts Z1, Z2, Z3 and Z4.

In practice, the photoelectric elementary receivers such as 50a and 51a will be arranged side by side and will have a diameter much smaller than the difference between the Z1-Z4 impacts. The second element 5b of the means 5 for receiving and isolating the light beam reflected by the membrane 1 scrutinizes the electrical signals coming from the matrix 5, distinguishes, by the relative position of the elementary photoelectric receivers such as 50a and 51a which receive them, the signals corresponding to the beam 4 reflected by the membrane 1, and outputs a signal d corresponding to the position of the impact Z3 of the light beam 4 reflected by the membrane 1. In practice, good results have been obtained using a matrix 5 with a single column, insofar as the incident light beam I interacts with the central zone of the membrane 1 when the latter is at rest. In the embodiment illustrated in FIG. 2, the measuring device according to the invention is associated with a device allowing the cleaning and the depollution of the photomask 100. The cleaning and decontamination device comprises control means 14, comprising a processor associated with a control program stored in a memory. The recorded program includes pumped gas extraction program sequences and purge gas introduction program sequences. The control means 14 control the pumping means 12 and the gas supply means 13. During pumping or gas introduction sequences, the membrane 1 undergoes different pressures on both sides of its faces. Pin 'is the pressure of the atmosphere in the confined environment of the photomask 100, that is to say the gas pressure between the lower face of the membrane 1 and the upper face of the support 6. Pext is the gas pressure around the photomask 100 in the sealed enclosure 9. These different pressures deform the membrane 1. In a preliminary step, in stable pressure Pext, the position of the impact Z3 is stored for example by the second element 5b of the means 5 to receive and isolate the light beam reflected by the membrane 1. In a first step, it wants to evacuate in the sealed chamber 9. The pumping means 12 lower the pressure Pext. The lower face of the membrane 1 is P; nt and its outer face Pext lower. The membrane 35 1 will then deform upwardly (or outwardly of the photomask). This deformation is illustrated by dotted lines 8a. The leak 7a tends to reduce the pressure difference on either side of the membrane 1, but this is not enough. The deformed membrane 1 reflects the incident light beam I, and the reflected beam 4 'will strike at Z'3 the first element 5a means 5 to receive and isolate the light beam reflected by the membrane 1. The second element 5b means 5 to receive and isolate the light beam reflected by the membrane 1, which has the role of sorting between the impacts Z ,, Z2, Z'3 and Z4, allows to consider only the impact Z'3, only point The measuring device according to the invention thus provides the electrical signal corresponding to the position of the impact Z'3. This signal is compared by the control means 14 to the position of the initial impact Z3, which is in memory, to determine the displacement d of the impact Z3. This displacement is the image of the deformation of the membrane 1. A test is then carried out by the control means 14 on the deformation d of the membrane 1. For this, the program of the control means 14 contains an algorithm according to which when the deformation d of the flexible membrane 1 measured by the sensor is less than a permissible deformation limit D, then the pumping or purge gas introduction sequence proceeds normally, according to the other instructions contained in FIG. program, - when the deformation d of the flexible membrane 1 measured by the sensor is at least equal to the allowable strain limit D, the pumping or purge gas introduction sequence is modified to voluntarily reduce the rate of change of gas pressure Pext in the sealed chamber 9, to reduce or not to increase the deformation d of the flexible membrane 1. Thus, if the deformation d of the membrane 1 is greater than greater than the admissible deformation D, the pumping is modified so as to reduce the deformation d of the diaphragm 1. The admissible strain limit D is chosen to be lower than the threshold of elastic deformation of the diaphragm 1. It depends on the diaphragm 1, pumping, process, and is determined by experience. During the second stage of the cleaning and depollution process, the environment of the sealed enclosure 9 is purged by introduction of a neutral gas, advantageously argon.

Thus Pext becomes greater than P; nt, the membrane 1 then deforms downwards, as indicated by the very tight dotted shape 8b.

The deformed membrane 1 reflects the incident light beam I, the reflected beam 4 "will strike in Z" 3 the first element 5a means 5 for receiving and isolating the light beam reflected by the membrane 1. The following process is similar to that described for the first step, with the difference that the gas supply means 13 is then controlled as a function of the measured deformation of the diaphragm 1. FIG. 3 illustrates the operation described below of the device of FIG. Figure 2, during a purge cleaning procedure. Curve A illustrates the temporal variation of the pressure Pext in the sealed enclosure 9. The curve B 10 illustrates the temporal variation of the position signal of the impact Z3, which is the image of the position of the zone of maximum deformation of the membrane 1. At the initial moment to, the pressure Pext in the sealed chamber 9 is the atmospheric pressure Pa. The control means 14 cause the pumping means 12 to act according to a normal pumping program sequence. The deformation measuring device permanently controls the deformation of the membrane 1, and produces a position signal (curve B) image of this deformation. Up to the instant t ,, the pressure Pext decreases according to a slope determined by the pumping parameters chosen by the recorded program of the control means 14. The rather rapid decrease of the pressure Pext causes the appearance of a differential pressure. the internal pressure P is decreasing less rapidly than Pext. This results in increasing deformation of the membrane 1 (curve B). At time t, the curve B of deformation of the membrane 1 reaches the limit D of admissible deformation. The control means 14 then detect this event, by the program algorithm, and modify the actuation of the pumping means 12, for example by reducing the speed of a pump or reducing the opening of a valve. control, to reduce the pumping speed and accordingly reduce the rate of decrease of the pressure Pext in the sealed enclosure 9. Ideally, the control means 14 reduce the pumping speed so that the deformation d remains in level, near the limit D, until the end of the pumping step. It can be seen in FIG. 3 that between the instants t, and t2 the deformation d is substantially constant and the pressure Pext decreases less rapidly than during the previous step between the instants t0 and t1.

At time t2, the desired low pressure P is obtained in the sealed enclosure 9, or the pressure appropriate for the clearance operation of the photomask 2908875 13 100. The control means 14 then resume the normal program flow, by reducing the pumping and by controlling the purge gas supply means 13 to introduce a purge gas into the sealed chamber 9. This results in a rise in pressure Pext, up to atmospheric pressure Pa.

Simultaneously, the deformation d decreases to zero. If the pressure rise Pext is too fast, the deformation d can be reversed and reach, in negative, the limit D. The recorded algorithm of the program then limits the flow of the gas supply means 13, to prevent the deformation d does not exceed the limit D.

It will be appreciated that the device can handle two different limits D 1 and D 2. For example, D + may be chosen a little lower than the limit of elastic deformation of the membrane 1, to prevent the rupture of the membrane 1, while D-may be chosen a little smaller than the distance between the membrane 1 at rest and the surface of the support 6, avoiding contact which would degrade the surface condition and optical quality of the membrane 1. The present invention is not limited to the embodiments which have been explicitly described, but includes the various variants and generalizations that are within the reach of those skilled in the art.

Claims (10)

  1. Non-contact measuring device for the deformation of a flexible membrane (1), transparent, fixed at its ends and subjected to a differential pressure, characterized in that it comprises means (3) for generating a light beam incident (I) and direct it obliquely towards the membrane (1), and means (5) for receiving and isolating the light beam (4) reflected by the membrane (1) and for measuring its displacement.   2. Measuring device according to claim 1, wherein the incident light beam (I) makes with the surface of the membrane (1) an angle of incidence (a) of about 56.   3. Measuring device according to one of claims 1 or 2, wherein the incident light beam (I) interacts with the central zone of the membrane (1). 15   4. Measuring device according to any one of claims 1 to 3, wherein the means (3) for generating an incident light beam (I) comprise a laser source, advantageously emitting radiation at a wavelength of about 900 nm.   5. Measuring device according to any one of claims 1 to 4, wherein the means (5) for receiving and isolating the reflected light beam (4) comprise an ordered matrix (5a) of photoelectric receivers (50a-51a). ) adapted to receive the beams reflected by the different surfaces lying in the path of the incident light beam (I), comprising the beam (4) reflected by the membrane (1), and to produce electrical signals amplitude images and the position of the light energy reaching the matrix (5a).   6. Measuring device according to claim 5, wherein the means (5) for receiving and isolating the reflected light beam (4) analyze the electrical signals coming from the matrix (5a), distinguish, by its relative position, the 30 signal corresponding to the beam (4) reflected by the diaphragm (1), and produce at output a signal corresponding to the position of the light beam (4) reflected by the membrane (1).   7. Use of a measuring device according to any one of claims 1 to 6 for controlling the deformation of a protective film (1) of a photomask (100) in a variable pressure atmosphere.   8. Use of a measuring device according to any one of claims 1 to 6 for limiting the pressure variations of the atmosphere surrounding a photomask (100) protective film (1).   9. Use of a measuring device according to any one of claims 1 to 6 for providing a signal that controls means (14) driving the pumping means (12) and / or the gas source (13). purging of a device for cleaning and decontamination of an object (100) confined environment leak-proof limited by a flexible membrane wall (1)   10. Use of a measuring device according to any one of claims 1 to 6 in a method for cleaning and depolluting a sealed non-sealed environment object (100) limited by a flexible membrane wall (1). . comprising the following steps: - placing the sealed non-sealed environment object (100) in a sealed enclosure (9) comprising means (13) for injecting a gas or mixture of purge gas and pumping means (12) the strain (d) of the diaphragm (1) is permanently measured by means of the measuring device, the gas contained in the sealed chamber (9) and the gas contained in the internal space of the non-sealed confined environment (100), and / or introducing a purge gas into the sealed enclosure (9) and into the interior space of the non-sealed confined environment object (100); pumping and / or the introduction of purge gas according to the signal given by the sensor, so as to keep the deformation (d) of the membrane (1) below a permissible limit of deformation (D).