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    • 专利摘要:
    The invention relates to a method for etching a layer to be etched in a plasma etching reactor, the method comprising at least one sequence of steps comprising at least: a step of forming a reactive layer (710) comprising a injection into the reactor of at least one reactive gas to form a plasma of reactive gas (s), the reactive gas plasma (s) forming with the layer to be etched a reactive layer (110) which enters the layer to be etched at as the etching of the layer to be etched, the parameters of the reactive layer forming step (710) allowing the reactive layer (110) to reach, at the end of a predetermined period of time method for injecting the reactive gas, a stationary thickness in time, characterized in that: the injection of the reactive gas is interrupted before said determined duration so that at the end of the step of forming a reactive layer (710) the thickness of the reactive layer (110) es less than said stationary thickness in time, and in that the sequence of steps comprises at least one step of removing (720) the reactive layer (110), the removing step (720) comprising an injection into the reactor of at least one neutral gas for forming a plasma of neutral gas (s) for removing only the reactive layer (110). The invention also relates to a system for implementing the invention.
    公开号:FR3017241A1
    申请号:FR1450781
    申请日:2014-01-31
    公开日:2015-08-07
    发明作者:Olivier Joubert;Gilles Cunge;Emilie Despiau-Pujo;Erwine Pargon;Nicolas Posseme
    申请人:Centre National de la Recherche Scientifique CNRS;Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    [0001] TECHNICAL FIELD OF THE INVENTION The present invention generally relates to dry etching techniques used in microelectronics and relates more particularly to improving the accuracy of this type of etching made from plasmas. STATE OF THE ART The constant reduction of the dimensions of the patterns which it is necessary to be able to engrave to produce ever denser integrated circuits could only be supported by constantly improving the techniques of photolithography and etching of the layers of materials used to produce electronic integrated circuits as well as all sorts of other devices of micrometric or even nanometric sizes combining optical and mechanical devices. After having used so-called "wet" engravings for a long time, in which the substrates to be etched are immersed in a suitable solution, capable of chemically reacting with and dissolving the material to be etched, the microelectronics industry has since many years now use so-called "dry" engravings. These are performed by ion bombardment of the target to be etched with a plasma formed in an etching chamber. Since the bombardment of the ions is essentially perpendicular to the surfaces to be etched, there is little or no lateral etching of the materials to be etched under optimal conditions of implementation, and the critical dimensions (CD) of the devices can be more easily reached. to produce. The main advantage of this type of etching is that it can be strongly anisotropic.
    [0002] However, plasma etching must be able to meet ever more difficult challenges to cope with the introduction of new families where technological "nodes" especially beyond that called "22 nm". The realization of the order of the order of tens of nanometers (nm) then poses the problem of the intrinsic precision of etching that can be obtained from a plasma. The main difficulty is that of the selectivity of the etching at the boundary between the layers of different materials of which the devices to be produced are made. This is illustrated in FIG. 1 which shows the surface layer 110 of a material 100 which is being etched and whose atomic structure is strongly disturbed by the bombardment 120 of the plasma ions from its surface 101. a plasma is in fact characterized by the fact that it is generally advantageous to impart to the ions coming to bombard the target a large amount of energy in order to obtain a high etching rate and therefore low etch times compatible with the criteria of implementation of an industrial manufacturing process. However, this significant energy results in the production of a disturbed layer 110, referred to as a reactive layer, which is itself of considerable thickness relative to the etching accuracies which it is desirable to obtain at the integration levels. considered, that is to say for technological nodes beyond that of 22 nm. This reactive layer 110 is usually several nanometers thick and can extend up to about ten nanometers.
    [0003] FIGS. 2a to 2e illustrate the problems that then arise for the plasma etching of electronic components of decananometric dimensions, essentially MOSFET transistors, which stands for "metal-oxide-semiconductor field effect transistor". or "metal-oxide-semiconductor field effect transistor" which essentially comprise the integrated circuits and other devices produced by the microelectronics industry. FIG. 2a illustrates the problem that arises more specifically when making planar MOSFET transistors of the FDSOI type, an acronym for the English language, referring to a very widely used technological process in which the transistors with conduction channels are produced which can be completely deserted from their carriers or "fully depleted" (FD). To obtain this result, we then start from elaborate silicon-on-insulator (SOI) substrates on the surface of which the transistors are made from a thin monocrystalline silicon layer 210.
    [0004] The plasma etching 120 of the gate electrodes of the FDSOI transistors is particularly delicate. The material or materials 100 forming the gate 220 must be etched on either side of a mask called "hard mask" 230 defining their horizontal geometry. The etching must be able to stop precisely in this case on a thin oxide layer 240, of the nanometer or even lower thickness, which has been formed on the single crystal layer 210 and without damaging the latter. It is indeed particularly important for the following steps not to disturb the monocrystalline structure of the layer 210 exposed to etching and to leave a sufficient thickness. FIG. 2b illustrates another problem that arises for plasma etching when producing another type of MOSFET transistor whose three-dimensional (3D) structure 200 has been developed more particularly for the decananometric technological nodes. These transistors are called "FinFET" acronym for English referring to the structure of their conduction channel 260 which in the form of a vertical fin or "end". In this case, a problem arises in particular when etching the gate on the one hand 290 and spacers on the other hand. When etching the grid that must be perfectly anisotropic, the etching must stop at the top of the END while continuing to the silicon substrate. When the etching reaches the base of the structure, the complete removal of the residues at the corner of the structures may require a very long (70-100%) supergraving time during which the top of the FIN is protected only by a layer of very thin oxide. We must then form the "spacers" 250 on both sides of the grid. Like the etching of the grid, the etching of the spacers requires a directional etching process which must minimize the lateral etching of the spacer without damaging the top of the END. Very long burn-in times (between 200 and 400%) are also required to remove nitride residues at the foot of the FIN. The risk of damage to the top of the END is real. The problem for the realization of this three-dimensional structure is not to damage the rectangular geometrical shape, and in particular the corners 280, of the END under penalty of seriously affecting the performance of this type of transistors whose characteristics and electrical behavior are directly related to the shape of the channel and the grid 290 surrounding it. The edges of the "ends" must also form angles that are as straight as possible with the layer on which these "ends" rest, typically the silicon layer.
    [0005] FIGS. 2c to 2d illustrate the very undesirable effects of a reactive layer 110 of a thickness much greater than that of the thin oxide layer 240 which ideally should be able to serve as a stop to etching. These figures show the progression 122 of the reactive layer 110 in the material to be etched 100. For the sake of clarity, the reactive layer 110 is shown in Figures 2c to 2d by a texture representing a disturbed atomic structure. The respective dimensions of the different layers are obviously not respected in these figures. The reactive layer 110, as shown in FIG. 2d, reaches up to the oxide layer 240 and then passes through, as shown in FIG. 2e thus causing an undesirable etching 212 of the underlying silicon layer 210 monocrystalline. FIG. 3 is a photograph taken under an electron microscope of a section of an FDSOI type transistor etched under the above conditions and which illustrates the problems posed by standard plasma etching. This photo shows the thin superficial layer 210 of monocrystalline silicon in which a very significant shrinkage 212 of this layer resulting from the etching of the gate electrode 220 can be observed. The shrinkage was caused here by the anisotropic etching of Grid spacers 250 which are traditionally made of silicon nitride and remained in place on the sides of the grid. To overcome the undesirable effects of an excessive reactive layer that is formed in the etching material placed in a standard etching plasma, it is therefore necessary to be able to very substantially reduce the thickness of the latter while trying not to affect too much. heavily the other parameters of the engraving, such as anisotropy, precision and etching time. FIGS. 4a and 4b set an exemplary objective of reducing the thickness of the reactive layer which must be aimed at conferring on the etching process the properties necessary in order to effectively obtain a sufficient etching precision for the HF technology nodes. beyond that currently in production that is to say that of 22 nm. FIG. 4a shows the thickness of the reactive layer 110 formed on the surface of silicon which is obtained in a standard manner under a weak ion bombardment. It is in this example of 3.5 nm and is obtained by communicating to the ions an energy of between 15 and 30 electrons-volts (eV) typically in a plasma type ICP, acronym of the English "inductively coupled plasma" c ' that is, "inductively coupled plasma", in which it is an induction coil surrounding the etching chamber which maintains the plasma. This result is further obtained by not applying bias voltage or "bias" to the silicon wafer on which the devices are made. To achieve this objective it is necessary, as shown in Figure 4b, very substantially reduce the reactive layer 110 to a thickness of not more than 1 nm. It is under these conditions that atomic precision engraving can be obtained, in which only a few layers of material to be etched are disturbed by the formation of a reactive layer. It must also simultaneously be able to maintain a displacement of the etching front, and therefore an etching rate, compatible with the implementation of an industrial process in a production line. Several solutions have been considered for engraving a very thin layer. In order to practice an atomic etching there is an etching process well known to those skilled in the art called ALET, an acronym for "atomic layer etching", that is to say "etching of a layer-by-layer material". where one repeats cycles of engraving which are self-limiting and remove, with each cycle, only one atomic layer. Such an etching process is for example described in an article in English published in 1996 in the "Journal of the American Vacuum Society" entitled "Realization of Atomic Layer Etching of Silicon" (J. Vac. Sci. Technol. B 14 (6) Nov / Dec 1996). Each cycle may comprise up to four steps during which an adsorption reagent is first introduced into the etching chamber in gaseous form. For example, for the etching of silicon, chlorine (Cl) is introduced. The excess chlorine is then purged and the reactant which has been adsorbed is exposed to ion bombardment. Etch products such as silicon-chlorine radicals (SiCI) are then removed after which the above cycle can be repeated. Such a technique, which is mainly practiced in the laboratory and for the development of new products, is intrinsically long. It typically takes 150 seconds to complete each cycle. The slowness of this process makes it not used industrially. To practice an atomic etching it is also possible to use a plasma with a low "electronic temperature", that is to say a plasma in which the temperature of the electrons is of the order of 0.5 eV. In this type of plasma, the ions that bombard the surface to be etched acquire an energy of the order of only 5 eV or less, which makes it possible to limit the reactive layer to a very small thickness. However, this type of low temperature electronic process has two serious drawbacks. The first is that low energy ions can deposit and form polymers. The other disadvantage is that the directionality of the low energy ions is smaller. The etching is no longer as anisotropic as with high energy ions, and it becomes difficult to respect the critical dimensions (CD) of the decananometric size transistors. Plasma etching at a low electronic temperature is therefore not considered a solution that is industrially viable at this level of integration. So-called pulsed plasmas are also known which make it possible to obtain, as desired, a reactive layer of small thickness, less than 1 nm. In this type of plasma, no polarization is applied to the target, that is to say to the substrate or the wafer to be etched, and the source is pulsed with a low duty cycle. The plasma is thus lit (time "ON") and off (time "OFF") at a fast frequency (between a few hundred Hz and a few kHz). The ratio of the times between the ON and OFF times is the duty cycle. A duty cycle of 20% means that the plasma is on for 20% of the duration of the period. Under these conditions, the energy imparted to the ions is lower than when the plasma operates in continuous mode, however the etching rate also becomes very low and does not meet the industrial objectives Typically, it is then necessary under these conditions tens or even hundreds seconds for etching for example 1 nm of polycrystalline silicon.
    [0006] As described above, the known solutions to perform etchings by controlling very precisely the stop of the etching all have disadvantages. The present invention therefore aims to describe an etching process which at least partially overcomes the disadvantages of known methods for performing accurate etchings. Other objects, features and advantages of the present invention will become apparent from the following description and accompanying drawings. It is understood that other benefits may be incorporated. SUMMARY OF THE INVENTION A process for etching a layer to be etched in a plasma etching reactor, the method comprising at least one sequence of steps comprising at least: a step of forming a reactive layer comprising an injection into the reactor of at least one reactive gas to form a plasma of reactive gas (s), the reactive gas plasma (s) forming with the layer to be etched a reactive layer which penetrates into the layer to be etched as and when engraving of the layer to be etched; and in which the injection of at least one reactive gas is interrupted before a determined injection period at the end of which the reactive layer would have reached a stationary thickness in time, so that at the end the injection of at least one reactive gas the thickness of the reactive layer is then less than said stationary thickness in the time. Preferably, the sequence of steps comprises at least one step of removing the reactive layer, the removal step comprising an injection into the reactor of at least one neutral gas to form a plasma of neutral gas (s) allowing remove only the reactive layer. Thus, the etching step comprises injecting into the etching reactor at least one reactive gas for a determined period of time as opposed to the methods of the state of the art where the reactive gas is injected continuously into the reactor. etching reactor. In the processes of the state of the art, and therefore when the gas is injected continuously into the reactor, the reactive layer reaches after a fixed time a stationary thickness which drives the etching process. In these etching processes with continuous gas injection, the stationary thickness reached by the reactive layer and the time at which this stationary thickness is reached depends on the parameters of the plasma. When the injection of the reactive gas is limited in time, the thickness of the reactive layer can be controlled and its thickness smaller than the thickness reached steady state when the gas is injected continuously.
    [0007] To minimize the thickness of the reactive layer, the injection of the reactive gas must be interrupted before the reactive layer reaches its stationary thickness when the reactive gas is injected continuously. The stationary thickness is typically the maximum thickness of the reactive layer when the reactant gas (s) is injected continuously, typically when injected for several seconds or several minutes. The step of forming the reactive layer is performed according to parameters that would have allowed the reactive layer to reach, at the end of the determined period of injection of the reactive gas, a stationary thickness over time.
    [0008] The use of a neutral gas makes it possible to physically spray the reactive layer formed in the previous step without continuing to feed the formation of the reactive layer. Thus, the invention makes it possible to control the dynamic formation of the reactive layer. The formation of this layer is stopped before it reaches the stationary thickness it would reach if the reactive gas was injected continuously. The invention thus makes it possible to very precisely control the thickness of the reactive layer and thus the stopping of etching. Therefore, the invention improves the accuracy of etching. Typically, the invention makes it possible to control the etching with an atomic precision and to stop the etching on extremely thin layers, with thicknesses of less than 1 nm without damaging the underlying layers.
    [0009] Thus, when the etching is carried out with a barrier layer, the thickness of the reactive layer is controlled so that its thickness remains less than or equal to a thickness beyond which it passes through the barrier layer and disrupts the underlying layer.
    [0010] Moreover, the invention makes it possible to retain the strong anisotropy of plasma etching. In addition, it may have an etching rate compatible with an industrial application, for example if the etching rate reached during the stage where the reactive gases are injected is high and the frequency of the reactive gas / neutral gas injection cycles. is fast.
    [0011] According to another embodiment, the invention provides a method of etching a layer to be etched in a plasma etching reactor, the method comprising at least one step of forming a reactive layer, this step comprising injection into the reactor of at least one reactive gas for forming a reagent gas plasma (s) capable of etching the layer to be etched, characterized in that the injection of the at least one reactive gas is carried out for a duration of less than 1000 milliseconds, preferably less than 500 milliseconds, preferably less than 200 milliseconds and preferably less than 100 milliseconds. The method preferably comprises at least one reactive layer removal step, the removal step comprising injecting into the reactor at least one neutral gas to form a neutral gas plasma (s) to remove the reactive layer . The removal step is preferably performed in part at least after the reactive layer forming step.
    [0012] According to yet another embodiment, the invention provides a method of etching a layer to be etched in a plasma etching reactor, the method comprising at least one step of injecting into the reactor at least one reactive gas for forming a reactive gas plasma (s) capable of etching the layer to be etched, characterized in that the injection of the at least one reactive gas is carried out for a duration of less than 1 second, preferably less than 500, preferably less than 200 milliseconds and preferably less than 100 milliseconds. The method comprises at least one withdrawal step, preferably carried out after the etching step, comprising an injection into the reactor of at least one neutral gas to form a neutral gas plasma (s). Preferably, the injection of the neutral gas is carried out for a period of less than 500 milliseconds and preferably less than 100 milliseconds.
    [0013] Optionally, the invention may furthermore have at least one of the following steps and characteristics which may be considered separately or in combination: Advantageously, the injection time of the reactive gas is between 50 to 1000 ms and preferably between 50 to 500 ms. Advantageously, the injection time of the reactive gas is interrupted when the reactive layer has a thickness of between 0.5 and 2 nm and preferably between 0.5 and 1 nm and preferably less than 1 nm and more generally less than 2 nm. According to one embodiment, the layer to be etched is on a barrier layer and the injection time of the reactive gas must be evaluated so that the reactive layer has a thickness less than the thickness of the barrier layer. The injection time of the reactive gas is interrupted before the reactive layer has a thickness greater than the thickness of the barrier layer. - Advantageously, the injection time of the neutral gas is less than 1 second, preferably less than 500 milliseconds and is preferably between 50 ms to 200 ms. According to one embodiment, the injection time of the neutral gas is between 50 ms and 500 ms and preferably between 100 and 500 ms. Thus the duration of the plasma of neutral gas (s) is included in these intervals. According to one embodiment, during the step of forming a reactive layer, at least one of the following parameters is adjusted so as to control the formation of the reactive layer: the injection time of the reactive gas and the energy communicated to the plasma ions of reactive gas (s). The other parameters of the plasma and the etching chemistry remaining identical to the conditions used for the process operating with an injection of the etching gases continuously. Preferably, during the etching step, at least one of the following etching parameters is adjusted so as to control the formation of the reactive layer: the injection time of the reactive gas, the pressure of the plasma, the reactive gas flow rates, the reactive gas plasma density (s) (by adjusting the RF power injected into the plasma), the energy imparted to the reactive gas plasma ions (s) (by adjusting the bias power applied to the substrate holder). Preferably, during the etching step, said etching parameters are preferably maintained identical to the conventional parameters for etching the material. Preferably, the energy communicated to the ions of the reactive gas plasma (s) during the reactive gas injection step is less than 100eV and preferably less than 50eV and preferably less than 25eV and the density of the plasma of reactive gas (s) is between 1010 and 5110 ions / cm3 and preferably between 1010 and 1011 ions / cm3. These values of the ion density and ion energy should make it possible to minimize the thickness of the reactive layer formed during the first step and to maintain its thickness less than a value of the order of 1 nm. If the results obtained show that the reactive layer is too thick (excessive consumption of a sub-layer for example or consumption of the substrate in case of stopping of the etching on a substrate or excessive consumption of a stopping layer at etching ), the plasma parameters may be modified or the injection time of the reactive gas reduced. Advantageously, during the step of removing the reactive layer at least one of the following parameters is adjusted so as to remove the reactive layer without removing the layer to be etched unmodified during the gas injection step reagent: the injection time of the neutral gas (s), the density of the neutral gas plasma (s), the energy communicated to the ions of the neutral gas plasma (s). The energy communicated to the ions of the neutral gas plasma (s) is adjusted so as not to spray the material of the layer to be etched nor to modify it. More generally, the parameters of the injection of the neutral gas are determined so as not to modify the material under the reactive layer formed during the reactive layer forming step (ie the material which has not been modified during the reactive gas injection step). Thus, the neutral gas does not damage the material to be etched. The neutral gas does not react chemically with the material to be etched. Preferably, the energy communicated to the ions of the plasma of neutral gas is less than 500 eV and preferably less than 100 eV and preferably less than 50 eV and preferably less than 30 eV and preferably less than 25 eV. the plasma of neutral gas formed during the step of removing the reactive layer is advantageously continuous for spraying the reactive layer faster. In continuous mode, the energy imparted to the ions of the plasma of neutral gas (s) is less than 50eV, preferably less than 30eV and preferably less than 25eV. This makes it possible to spray the reactive layer without damaging the underlying layer. Alternatively, the neutral gas plasma is pulsed (plasma excitation source power and polarization power of the substrate can be pulsed synchronously). According to one embodiment, the neutral gas plasma formed during the step of removing the reactive layer is a pulsed plasma and the energy communicated to the ions of the neutral gas plasma is less than 50eV. and preferably less than 25eV. According to a particular embodiment, a radiofrequency (RF) polarization is applied to the substrate on which the layer to be etched rests. This accelerates the removal of the reactive layer by imparting energy to the ions that bombard the substrate. The polarization power is advantageously between 0 and 500W, preferably between 0 and 100W and preferably between 0 and 20W. Advantageously, during the step of removing the reactive layer, only a neutral gas or a mixture containing only neutral gases is injected. According to a particular embodiment, during the step of forming the reactive layer, a neutral gas or a mixture of neutral gases is injected in addition to the reactive gas. It is indeed possible to inject a mixture of neutral gas during the injection of the reactive gas. A continuous neutral gas stream is thus left in the reactor and only the injection of the reactive gas into the plasma is pulsed. According to one embodiment, said removal step comprising an injection into the reactor of at least one neutral gas is carried out continuously and simultaneously with a plurality of said injections of at least one reactive gas.
    [0014] Thus, the reactive gas (s) is injected in a pulsed or discontinuous manner and the neutral gas (s) is injected continuously. Alternatively, the reactive gas (s) is injected in a pulsed or discontinuous manner and the neutral gas (s) is injected in a pulsed or discontinuous manner. Preferably, the injection of reactive and neutral gas is alternated. - The reactive gas is able to burn the material in a plasma reactor. According to a particular embodiment, the reactive gas is taken from all of the reactive gases or reactive gas mixtures which make it possible to etch the material that is to be etched. This selection is absolutely identical to an etching process where the gases are injected continuously into the etching chamber. In other words, all the knowledge in the field of plasma etching is applicable, the pair of etching gas / material to be etched is unchanged. The parameter that is advantageously changed in the context of the invention is the injection time of the reactive gas in the reactor compared to the situation where it is typically injected continuously. According to one embodiment, the reactive gas is taken from chlorine C12, HBr, SF6, NF3, SiCl4, BCI3, H2, SiF4, O2, HCl, HI, CH2F2, CHF3 Ar or a mixture of these gases. for front end processes. According to one embodiment, the reactive gas is taken from CF4, CHF3, CH3F, C4F8, CH2F2, C4F6, C5F6, Ar, O2, He or any other reactive gas. used for etching dielectrics. According to one embodiment, the neutral gas is a rare gas or a mixture of rare gases. According to one embodiment, the neutral gas is argon (Ar), xenon (Xe) or a mixture of these gases. According to a particular embodiment, the layer to be etched is made of semiconductor material or a metal or a high permittivity dielectric material or any layer of material included in a stack of complex materials involved in the preparation of transistors or interconnections that make it possible to produce a microelectronic device. This concept of injection of gases during a controlled period of time (pulsed gas injection) is very general and can be applied to any process of plasma etching of any material. In some cases, pulsing the reactive gases will not be of interest while in other cases and in particular when the accuracy of the etching must be controlled at the ready nm, control the injection time of the reactive gas will be necessary. Preferably, the layer to be etched is made of semiconductor material selected from: silicon (Si), germanium (Ge) or silicon-germanium (SiGe) or InGaAs, or graphene, or MoS2 or a thin layer to base of III-V materials or a metal layer or layer of porous dielectric materials. The layer to be etched may also be a metal selected from Ti, Ta, TaN, TiN, W, Cu or any metal that may be involved in a microelectronic device.
    [0015] The layer to be etched may be a high permittivity dielectric material such as HfO 2, Al 2 O 3, Hf SiON, ZrO 2, Y 2 O 3, etc. The layer to be etched may also be an oxide, or a nitride or an oxynitride or a dielectric material with a low permittivity or still a polymeric material such as a photoresist (193 nm resin or EUV resin). All of the above-mentioned layers may be flat thin layers or deposited on complex three-dimensional structures. According to one embodiment, the layer to be etched is a layer of a MOSFET transistor. According to one embodiment, said sequence of steps is carried out several times. According to one embodiment, the reactive gas and / or the neutral gas is different between at least two sequence of steps. Advantageously, the reactive gas injection steps of the layer to be etched and the removal of the reactive layer are carried out in the same plasma reactor, which simplifies the process. - The plasma reactor is a standard plasma reactor. Advantageously, the invention does not require a specific plasma reactor but a specific gas panel for injecting the gases during the appropriate periods of time (making it possible to pulsate the injection of the gases into the etching reactor). According to a particular embodiment, the layer to be etched may be flat or deposited on patterns. Advantageously, several sequences of steps are carried out. This makes it possible to control in a particularly precise manner the depth of advance of the reactive layer in the material to be etched. According to a particular embodiment, prior to the sequence of steps, an initial etching step is carried out, the initial etching step comprising an injection into the reactor of at least one reactive gas to form a reactive gas plasma. (s) initial, the injection duration being greater than said determined duration so that the thickness of the reactive layer reaches said stationary thickness in time. This makes it possible to perform an etching according to the conventional etching mode in which the gases are injected continuously and therefore very rapidly during which the reactive layer has its maximum thickness, and then to implement the sequence of steps which make it possible to limit the thickness of the reactive layer when it is needed only, that is to say if the plasma must land selectively on a very thin layer of nanometric thickness. If the thickness of the material to be etched is several tens of nanometers or several micrometers or more, it will thus advantageously be possible to carry out this approach step allowing rapid conventional etching under typical plasma conditions (without pulsing the injection of the reactive gases ), then, when the material has been etched to its almost complete thickness, said sequence of steps with pulsed gas injection is used. In the present patent application, the thickness of the reactive layer is taken in a direction perpendicular to the main plane in which extends the substrate is parallel to the preferred direction of the anisotropic etching. According to another embodiment, the invention relates to a system for carrying out the method according to the invention, the system comprising: a plasma etching reactor; an injection device configured to inject, preferably alternately, at least two gases in the plasma etching reactor, the injection device being configured to inject at least one of the gases for a period of less than 1000 milliseconds and preferably less than 500 milliseconds and preferably less than 100 milliseconds. The system thus makes it possible to form a reactive gas plasma (s) in a pulsed manner in the reactor alternately with a plasma of neutral gas (s). The injection device thus makes it possible to inject a first gas or a first gas mixture into the plasma reactor and then to interrupt this injection after a very short time beyond which it injects a second gas or a second gas. gas mixture for a very short time. The system is configured to repeat this sequence as many times as necessary. BRIEF DESCRIPTION OF THE FIGURES The objects, objects, as well as the features and advantages of the invention will become more apparent from the detailed description of an embodiment thereof which is illustrated by the following accompanying drawings in which: FIG. 1 shows the surface layer of a material being etched whose atomic structure is strongly disturbed by the bombardment of the ions of a plasma.
    [0016] Figures 2a to 2e illustrate the problems that arise for the plasma etching of electronic components of decananometric dimensions. FIG. 3 is a photograph of a section of a FDSOI type transistor etched with standard plasma etching. FIGS. 4a and 4b set the objective of reducing the thickness of the reactive layer that must be aimed at giving the etching process of the invention the properties necessary in order to effectively obtain a sufficient etching precision for the technological nodes. décananométriques. FIG. 5 (atomistic simulation) illustrates the formation of the reactive layer as a function of fluence in a plasma comprising Cl radicals and Cl + ions for different ion bombardment energies. FIG. 6 illustrates the time required to form a reactive layer of 1 nm as a function of time and the composition of the reactive gas plasma (s).
    [0017] Figure 7 depicts the sequence of steps of the method of the invention. FIG. 8 illustrates the repetition cycle of the steps of the etching process of the invention. FIG. 9 illustrates the growth dynamics of the reactive layer as a function of the injection time of the reactive gas and shows the influence of the energy imparted to the ions. Figure 10 illustrates the amorphization of the material underlying the one being etched at the stop of the latter. FIGS. 11a and 11b compare the standard method of etching the MOSFET transistor nitride spacers and the method of the invention applied to this case. The drawings are given by way of examples and are not limiting of the invention. They constitute schematic representations of principle intended to facilitate the understanding of the invention and are not necessarily at the scale of practical applications. In particular, the relative thicknesses of the different layers are not representative of reality. DETAILED DESCRIPTION OF THE INVENTION It is pointed out that in the context of the present invention, the term "over", "overcomes" or "underlying" or their equivalent does not necessarily mean "in contact with". For example, the deposition of a first layer on a second layer does not necessarily mean that the two layers are in direct contact with one another, but that means that the first layer at least partially covers the second layer. being either directly in contact with it or separated from it by another layer or another element. In the following description, the thicknesses are generally measured in directions perpendicular to the plane of the lower face of the layer to be etched or a substrate on which the lower layer is disposed.
    [0018] Thus, the thicknesses are generally taken in a vertical direction in the figures shown. On the other hand, the thickness of a layer covering a flank of a pattern is taken in a direction perpendicular to this flank.
    [0019] The invention will now be described in more detail with reference to Figures 5-11b. The invention is partly based on the observation of the reactive layer formation dynamics which is illustrated in a first example in FIG. 5. It is recalled here that the reactive layer is formed by a portion of the layer to be etched which is disrupted by the synergy between ion bombardment and plasma radicals of reactive gas (s) during plasma etching. The thickness and composition of the reactive layer depend on the plasma excitation parameters (pressure, gas flow and nature of the gases, ion energy, plasma density, photon flux). In a first approximation, the quantities that play a role in the formation of the reactive layer are: the density of the ions that bombard the substrate, the energy of the ions that bombard the substrate, the atomic and molecular radical flows that bombard the substrate, the flow of photons that bombard the substrate and the temperature of the substrate. The formation, the thickness and the chemical composition of the reactive layer thus depend essentially on the species flows that reach the substrate and the synergies between these parameters. When it has reached its stationary thickness, the reactive layer propagates in the material to be etched as the etching progresses. The reactive layer extends from the surface of the layer to be etched and in the direction of implantation. The reactive layer is a layer of the original material that has been disturbed by the reactive gas plasma (s). It consists of the original material that is "mixed" with the reactive species of the plasma. Its thickness is measured according to the preferred direction of plasma etching, that is to say in the preferred direction of ion bombardment. This direction corresponds to the vertical in Figures 2c-2e for example. Typically, the thickness of the reactive layer may in certain cases be measured by ellipsometry (by means of models) or by XPS (X-ray photoelectron spectroscopy or by transmission electron microscopy) type surface analyzes. In typical plasma etching conditions the reactive layer 110 usually measures several nanometers in thickness and can extend up to about ten nanometers. It is observed that in a chlorinated plasma having a density of 5 × 10 10 ions / cm 3 and in which the ions are given an energy of 50 eV the equilibrium state of the reactive layer in silicon, that is to say the thickness it reaches when the plasma is stabilized (thickness also referred to in this description stationary thickness), is obtained after about 300 ms of plasma. Figure 5 illustrates the growth of the reactive layer as a function of time for different ion bombardment energies. The ordinate axis corresponds to the thickness of the layer in angstroms. The bombardment energy is indicated on the right of each layer. These curves show that the layer reaches its full thickness of 2 nm in this case in about 400 (ms) for an ion energy of 50 eV. . These results are obtained on the basis of atomistic simulations. These values are therefore only indicative and gives an idea of the characteristic times in the case of a simple system in which the material is silicon and the reactive gas is chlorine. In practice, the materials are etched from reactive gas mixtures. In the context of the present invention, it has been identified that the growth dynamics of the reactive layer depends on the density of the ions and their energy. As far as density is concerned, the time required to obtain a stable reactive layer is all the lower as the density of the ions is high. It is the same with the energy of the ions, the higher it is, and the shorter the time required to reach the stability of the reactive layer (see FIG. 5). It can be seen from FIG. 5 that if the plasma is a pure chlorine plasma, the characteristic formation time of the SiCIx layer is of the order of 100 ms if the ion density is 1 mA / cm 2 and if ion energy is 100 eV. The method according to one embodiment of the invention takes advantage of the reactive layer forming dynamics described above to control the etching process to achieve the desired accuracy. As we have just seen, the dynamic conditions for establishing the reactive layer depend on the density of the etching plasma and the energy imparted to the ions. Advantageously, a control of the injection of gases into the etching chamber is added to keep the reactive layer in a low thickness range before it stabilizes at its equilibrium thickness.
    [0020] FIG. 6 illustrates the time required to form a reactive layer of 1 nm under various conditions (Cl + ions, Cl + ions, Cl + ions, C12 + ions, Cl + C12 + ions). These results are obtained by atomistic simulation and show that for a chlorine plasma having an ion density of 1mA / Cm2 and ions of energy greater than 50 eV, the reaction layer establishment times are low, typically lower than at 20 ms. To reach times of the order of 100 ms, the energy of Cl + or C12 + ions must be less than 25 eV. These results show, in the case of the silicon / chlorine layer to be etched for reactive gas, that moderate bombardment energies will be necessary to form reactive layers whose thickness will remain below the nm, even by controlling the injection times of the nanoparticles. gas in the plasma reactor in a time range of the order of 100 ms. It is also noted that the presence of chlorine radicals, for an energy of between 25 and 50eV, seems to slow the formation of the reactive layer.
    [0021] Figure 7 depicts the sequence of steps of the method of the invention. During a first step 710, the plasma, referred to as the reactive plasma or the etching plasma, is maintained under the etching conditions which would typically be those of a continuous etching of the layer to be etched and which would normally lead to the formation of a reactive layer of the order of several nanometers as described in the example of Figure 5. However, these conditions are maintained for a very short time so that the reactive layer can never stabilize and grow at a low value, typically of the order of 1 nm. More generally, the etching conditions are maintained for a period of time sufficiently short to prevent the reactive layer from reaching its stationary thickness. To obtain this result, the injection of the reactive gas into the etching chamber is controlled, as for example chlorine in the preceding example. The reactive gas can also be diluted in a neutral gas if the injection time of the gas for which gets a reactive layer of thickness less than 1 nm is too short (typically less than 100 ms). Stopping the growth of the reactive layer is obtained by stopping the entry of the gas when the thickness thereof has reached a predetermined value less than the thickness of the reactive layer in steady state. Typically, the target value is of the order of 1 nm which allows an atomic precision engraving. More generally, this predetermined value is less than 2 nm. In a second step 720, of a duration as short as possible, the reactive layer is removed in a plasma based on neutral gas which does not react with the material to be etched, so that this plasma-based neutral gas does not cause spraying of the material to be etched. This plasma is called neutral plasma. The ions of this plasma do not react chemically with the layer to be etched. The use of a neutral gas makes it possible to physically spray the reactive layer formed in the previous step without continuing to feed the formation of the reactive layer. Thus, the neutral plasma must make it possible to remove the reactive layer without etching the underlying layer or the substrate. The plasma conditions used are therefore chosen to spray only the reactive layer without spraying the underlying layer or the substrate. Since the neutral gas plasma does not react chemically with the material of the layer to be etched, its role is therefore limited to removing the reactive layer and thus to etching the thickness of material modified by the reactive layer during the injection step reactive gas for a limited time.
    [0022] Preferably, the neutral gas is a gas belonging to the so-called rare gas group of the periodic table of the elements (column 18). Preferably, it is argon (Ar) or Xenon (Xe). In this second step the polarization power or "bias" applied to the target must be controlled to promote the removal of the reactive layer. For example, in the current case in which silicon (Si) is etched in a reactive plasma based on chlorine (Cl), it is necessary to remove the monolayer of SiClx formed without causing spraying of the etched material, the silicon in this example . To do this, the energy communicated to the ions of the plasma of neutral gas (s) in this second step must remain below a threshold beyond which there would be spraying of the etched material. The sequence of the two steps above must be as fast as possible and repeated 730 until the material to be etched is removed over the entire thickness that it is desired to engrave. Typically, when etching is to be stopped on a barrier layer, the sequence of steps 710, 720 is repeated until complete removal of the material to be etched with possible stopping of the etching with atomic accuracy. Figure 8 illustrates the repetition cycle of the above steps. The reactive gas, for example chlorine, is introduced into the etching reactor for a period of time ranging from 100 milliseconds to several hundred milliseconds. During this period of time when the reactive layer is formed, the operating conditions of the etching chamber are those which would be used with a continuous plasma and which would therefore lead, as we have seen, to the formation of a reactive layer that is too reactive. thick. In particular, the power applied to the radiofrequency (RF) source 830 and that applied to the polarization 840 are similar to the conditions of a continuous etching or possibly the polarization power can be reduced to maintain the energy of the ions at a minimum. value of 50 eV or more probably less than 25 eV. The neutral gas, for example argon, is introduced into the etching reactor for a so-called toFF time 820 also typically from one hundred milliseconds to several hundred milliseconds. During this time the RF power of source 830 is adjusted to be as high as possible 832 to produce a plasma of very low density (s) gas (s) so as to shorten this step by eliminating the layer as quickly as possible. reactive which was formed in the previous step. At the same time, the biasing power 842 is adjusted to maintain ion energy below the sputtering threshold, typically below 20 eV. The step 710 of forming the reactive layer is in summary carried out under the following conditions: The simplest approach to form the reactive layer is to use parameters for the formation of the plasma of reagent gas (s) identical to those used in a standard continuous mode of etching and stop the injection of the reactive gas when a layer of the order of 1 nm or less has been formed on the material to be etched. The injection of the reactive gas is typically carried out in a time range of 100 to 500 ms. If necessary, the energy of the ions can be adjusted (reduced) to maintain the thickness of the layer to a thickness of less than 1 nm - The power of the source can be kept constant if reducing the injection time of the gas into the range of 100 ms or more, an ultra-thin reactive layer of 1 nm or less can be formed. If the injection time of the gas must be less than 100 ms, the density of the reactive gas plasma can be decreased. The decrease in the density of the plasma increases the time at which the equilibrium state of the reactive layer is reached. Therefore, the injection time of the reactant gas for which a thickness of 1 nm of the reactive layer is obtained also increases. - The power of the RF bias ("bias"), which controls the energy imparted to the ions, can be kept constant if the injection time of the reactive gas is not less than 100 ms to limit the thickness of the reactive layer at a thickness of less than 1 nm. If this is not the case, the reduction of the energy imparted to the ions via the polarization is an effective means for slowing down the formation rate of the reactive layer. Ion energy is the most efficient parameter for slowing down the formation rate of the reactive layer. A maximum reduction of energy imparted to the ions is possible by applying no polarization on the substrate. In this case the ion energy is eVp (Vp is the potential of the plasma) and generally does not exceed 20 eV in inductively coupled plasmas. A pulsation of the power of the plasma source with a low duty cycle allows an even greater reduction in the energy imparted to the ions if necessary. The diagram of FIG. 9 also illustrates the growth dynamics of the reactive layer as a function of the injection time of the reactive gas and shows the influence of the energy imparted to the ions. The curves 910 and 920 correspond to different energies. When the energy imparted to the ions decreases, this slows down the growth of the reactive layer. FIG. 9 illustrates the most effective means available for obtaining, during the first step 710, the desired thickness of the reactive layer: the injection time of the reactive gas, the energy communicated to the ions. Another way could be to vary the density of the plasma. However, this parameter would considerably modify the gas phase of the plasma, which is not desired in order to remain as close as possible to the optimized process under continuous plasma conditions (without injection of gas controlled over time). With regard to the second step 720 of the process, which is preferably carried out in a plasma of neutral gas (s) formed from, for example, a rare gas such as argon (Ar) or xenon (Xe), the latter must be adjusted to allow rapid removal of the reactive layer that was formed in the previous step 710. During this step the energy communicated to the ions must be such that it must allow the spraying of the reactive layer formed during the first step. This is, for example, in the case of the etching of silicon (Si) in a chlorinated plasma (Cl) of SiCIx compounds. Moreover, the energy imparted to the ions must remain below the sputtering threshold of the material to be etched, the silicon in this example. In an argon-based plasma and for silicon etching, the energy imparted to the ions must be less than 30 eV and if possible 20 eV.
    [0023] On the other hand, during the second step 720, the plasma using one of the neutral gases, for example argon, can operate in continuous mode. This step should be as fast as possible and the continuous mode should preferably be used with high source power, typically greater than 500 W. Polarization power can be applied to the wafer since the energy of the ions is maintained below the threshold of sputtering silicon or any other material on which the etching must stop.
    [0024] In order to limit the plasma induced amorphization depth in silicon, and in other etched materials in general, the ion energy must remain below 30 eV and preferably below 20 eV. In this case, the amorphization depth is limited for silicon to values less than 1 nm. Very high RF source powers, greater than 1000 watts in 300 mm inductive coupling reactors, generate rare gas plasmas (argon, xenon,) at very high densities in a range from 1011 to 1012. The so-called VUV light , the acronym for "vacuum UV" corresponding to ultraviolet radiation of short wavelengths, generated by these neutral plasmas also contributes to the etching. Thus, the increase of the source power not only contributes to obtain very high densities of ions, but also promotes the production of a very large flow of VUV light which contributes to the elimination of the reactive layer formed during the first step. Figure 10 illustrates the amorphization of the underlying material to that being etched at the stop of the latter. Figure 10 relates to silicon. It shows that the amorphization of this material becomes too important when the energy of the ions exceeds the range of values ranging from 20 to 30 eV. Diagram 1110 shows the thicknesses of silicon made amorphous as a function of the fluence of the argon ions used in this example and for different energies communicated to these ions, including the following values: 20 eV 1120; 50 eV 1130; 100 eV 1140 and 200 eV 1150. The amorphous thickness increases when the energy imparted to the ions increases. FIGS. 11a and 11b compare the standard method of etching the nitride spacers of MOSFET transistors and the method of the invention applied to this case.
    [0025] FIG. 11a illustrates the prior art in which the etching is carried out in an ICP type etching chamber using a fluorocarbon based trifluoromethane (CHF3) plasma with an application of a source power of 150 watts and a polarization power of 8 watts. These conditions are maintained throughout the duration of the etching. It can be seen that a thin layer of fluorinated carbon (CFx) 1410 and a thick layer of fluorine-doped silicon oxide (SiOF) 1420 forming the reactive layer which is propagated during etching are formed. the silicon nitride (SiN) layer 1430 for forming the spacers. At the end of the etching 1440, which always includes an overgravity time to take into account the thickness dispersions at the wafer level and to ensure the complete etching of the three-dimensional patterns, the reactive layer is finally transferred into the underlying material, c that is to say in crystalline silicon 1450 in this case, which is then oxidized 1460 over a large thickness with the drawbacks mentioned above in FIG. 3 which is described in the chapter on the state of the art. FIG. 11b illustrates the process of the invention where, as previously described, the injection of a reactive gas 810 and the injection of a neutral gas 820 are alternated. The plasma of reactive gas (s) formed during injection of the reactive gas is typically, as in the prior art described in Figure 11a, a trifluoromethane fluorocarbon plasma (CHF3). As already mentioned above, in the phase where the reactive gas is introduced, the plasma can work in pulsed synchronized mode (source power and bias power are pulsed synchronously) or in continuous mode. When working in pulsed synchronized mode, the frequency of the pulses is typically between 1000 hertz and 5 kHz. Their duty cycle is between 10 and 100% and the RF power delivered at the source between 100 and 2500 watts. During this phase the polarization power can be zero. It is generally low and in a range of 0 to 75 watts. During phase 820, where a rare gas, for example argon, is introduced, the power is always applied continuously to the source while the polarization is optimized while remaining below the silicon sputtering threshold in order to remove the reactive layer as quickly as possible.
    [0026] Under these conditions, the SiOF layer 1420 formed during the phase 810 is very fine 1422 which results in a very low oxidation 1462 of the underlying silicon after the etching of the nitride layer 1430.
    [0027] As is clear from the foregoing description, the invention thus makes it possible to considerably reduce the thickness of the sampled layer or at least to precisely control the stopping of etching, for example in silicon, by minimizing its consumption. Depending on the parameters used, it makes it possible to remove a thickness of less than 1.5 nm or even less than 0.5 nm for etching control up to an atomic accuracy. The invention is not limited to the only embodiments and embodiments described above, but extends to all the embodiments falling within the scope of the claims.
    权利要求:
    Claims (23)
    [0001]
    REVENDICATIONS1. A process for etching a layer to be etched in a plasma etching reactor, the method comprising at least one sequence of steps comprising at least: a step of forming a reactive layer (710) comprising an injection into the reaction reactor; at least one reactive gas for forming a reagent gas plasma (s), the reagent gas plasma (s) forming with the layer to be etched a reactive layer (110) which penetrates into the layer to be etched, characterized in that the injection (710) of at least one reactive gas is interrupted before a determined injection period at the end of which the reactive layer (110) reaches a stationary thickness over time, at the end of the injecting (710) at least one reactive gas, the thickness of the reactive layer (110) being then less than said stationary thickness over time, and in that the sequence of steps comprises at least one withdrawal step ( 720) of the reactive layer (110), the step of removing (720) comprising injecting into the reactor at least one neutral gas to form a neutral gas plasma (s) for removing only the reactive layer (110). 20
    [0002]
    2. Method according to the preceding claim, wherein the injection time (810) of the reactive gas is between 50 and 500 ms.
    [0003]
    3. A process according to any one of the preceding claims, wherein the injection time (810) of the reactant gas is interrupted when the reactive layer (110) has a thickness of less than 2 nm and preferably less than 1 nm.
    [0004]
    A method according to any one of the preceding claims, wherein the layer to be etched overcomes a barrier layer and the injection time (810) of the reactant gas is interrupted before the reactive layer (110) exhibits a thickness greater than the thickness of the barrier layer.
    [0005]
    5. Method according to any one of the preceding claims, wherein the injection time (820) of the neutral gas is between 50 ms and 500 ms and preferably between 100 to 500 ms.
    [0006]
    The method of any one of the preceding claims, wherein during the step of forming a reactive layer (710) at least one of the following parameters is adjusted to control the formation of the reactive layer. (110): the injection time (810) of the reactive gas and the energy communicated to the ions of the reactive gas plasma (s).
    [0007]
    7. Process according to any one of the preceding claims, in which the energy imparted to the ions of the plasma of reactive gas (s) is less than 50eV and preferably less than 25eV and the density of the plasma of reactive gas (s) is between 1010 and 5.1011 ions / cm3 and preferably between 1010 and 1011 ions / cm3.
    [0008]
    The method according to any one of the preceding claims, wherein during the step of removing (720) the reactive layer (110) at least one of the following parameters is adjusted so as to remove the reactive layer ( 110) without removing the etch layer not etched during the step of forming a reactive layer (710): the duration of injection (820) of the neutral gas, the density of the plasma of neutral gas (s), l energy communicated to the ions of the plasma of neutral gas (s).
    [0009]
    9. A method according to any one of the preceding claims, wherein the energy imparted to the ions of the plasma of neutral gas (s) is less than 50eV and preferably less than 25eV.
    [0010]
    10. A method according to any one of the preceding claims, wherein the plasma of neutral gas (s) formed during the step of withdrawal (720) of the reactive layer (110) is a pulsed plasma and the energy communicated toions neutral gas plasma (s) is less than 50eV and preferably less than 25eV.
    [0011]
    11. A method according to any one of the preceding claims, wherein the electrolytic layer is etched or a substrate on which the layer to be etched rests.
    [0012]
    12. A method according to any one of the preceding claims, wherein during the step of forming a reactive layer (710) is injected a neutral gas or a mixture of neutral gases in addition to the reactive gas.
    [0013]
    13. Process according to any one of the preceding claims, in which the reactive gas is taken from C12, HBr, SF6, NF3, SiCl4, BCI3, H2, SiF4, O2, HCl, HI, CH2F2, CHF3 Ar, or is taken from CF4, CHF3, CH3F, C4F8, CH2F2, C4F6, C5F6, Ar, O2, He or a mixture of these gases.
    [0014]
    The process according to any one of the preceding claims, wherein the neutral gas is a noble gas or a mixture of noble gases.
    [0015]
    15. A process according to any one of the preceding claims, wherein the neutral gas is argon (Ar), xenon (Xe) or a mixture of these gases.
    [0016]
    The method of any of the preceding claims, wherein said removing step (720) comprising injecting at least one neutral gas into the reactor is performed continuously and simultaneously with a plurality of said injections (710). at least one reactive gas.
    [0017]
    17. Process according to any one of the preceding claims, in which the layer to be etched is made of semiconductor material selected from: silicon (Si), germanium (Ge) or silicon-germanium (SiGe) or base of III-V materials or a metal layer or layer of porous dielectric materials.
    [0018]
    18. The method of any one of claims 1 to 16, wherein the layer to be etched is a layer of a MOSFET transistor.
    [0019]
    19. A method according to any one of the preceding claims, wherein said sequence of steps (710, 720) is performed several times. 10
    [0020]
    20. The method of any of the preceding claims, wherein the reactive gas and / or the neutral gas is different between at least two sequence of steps (710, 720).
    [0021]
    21. A method according to any one of the preceding claims, wherein prior to the sequence of steps, an initial etching step is carried out, the initial etching step comprising an injection into the reactor of at least one reactive gas. to form an initial reactive gas plasma (s), the injection duration being greater than said determined duration so that the thickness of the reactive layer (110) reaches said stationary thickness over time.
    [0022]
    22. A process for etching a layer to be etched in a plasma etching reactor, the method comprising at least: a step of forming a reactive layer (710) comprising an injection into the reactor of at least one reactive gas for forming a reactive gas plasma (s) capable of etching the layer to be etched, a reactive layer forming on the surface of the layer to be etched under the effect of the plasma of reactive gas (s), characterized in that: injection of the reactive gas is carried out for a period of less than 1000 milliseconds, and in that the process comprises at least one step (720) of removing the reactive layer (110), carried out in part at least after the step of forming the reactive layer (710), the removing step (720) comprising injecting into the reactor at least one neutral gas to form a neutral gas plasma (s) for removing the reactive layer (110).
    [0023]
    23. A system for carrying out the method according to any one of the preceding claims, comprising: a plasma etching reactor; an injection device configured to inject at least two gases into the plasma etching reactor; injection being configured to inject at least one of the gases for a time less than 1000 milliseconds and preferably less than 500 milliseconds.
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    同族专利:
    公开号 | 公开日
    FR3017241B1|2017-08-25|
    US20150228495A1|2015-08-13|
    US9378970B2|2016-06-28|
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    法律状态:
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    2018-01-26| PLFP| Fee payment|Year of fee payment: 5 |
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    2022-01-31| PLFP| Fee payment|Year of fee payment: 9 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1450781A|FR3017241B1|2014-01-31|2014-01-31|PLASMA ETCHING PROCESS|FR1450781A| FR3017241B1|2014-01-31|2014-01-31|PLASMA ETCHING PROCESS|
    US14/610,490| US9378970B2|2014-01-31|2015-01-30|Plasma etching process|
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