KR102482734B1 - Method for plasma etching ultra high aspect ratio using radio frequency pulse source and low frequency pulse bias - Google Patents

Abstract

The present invention relates to a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, and more particularly, a high-frequency pulse is applied to a source electrode of a plasma device, and a high-frequency pulse is applied to a bias electrode of the plasma device. By applying a low-frequency pulse only while it is not being applied, the density of active species is controlled, and at the same time, the density of ions and the energy of ions reaching the substrate are independently controlled to maintain the critical dimension of the mask during the etching process and ions with high energy Provided is a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias capable of performing ultra-high aspect ratio etching.

Description

Plasma extremely high aspect ratio etching method using high frequency pulse source and low frequency pulse bias

The present invention relates to a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, and more particularly, a high-frequency pulse is applied to a source electrode of a plasma device, and a high-frequency pulse is applied to a bias electrode of the plasma device. By applying a low-frequency pulse only while it is not being applied, the density of active species is controlled, and at the same time, the density of ions and the energy of ions reaching the substrate are independently controlled to maintain the critical dimension of the mask during the etching process and ions with high energy It relates to a plasma ultra-high aspect ratio etching method using a high-frequency pulse source capable of performing ultra-high aspect ratio etching by and a low-frequency pulse bias.

Plasma is widely used in manufacturing processes such as semiconductors, plasma display panels (PDPs), liquid crystal displays (LCDs), and solar cells. Representative plasma processes include dry etching, plasma enhanced chemical vapor deposition (PECVD), sputtering, and ashing. Typically, capacitively coupled plasma (CCP) Plasma), Inductively Coupled Plasma (ICP), Helicon plasma, Microwave plasma, etc. The plasma process depends on plasma variables such as electron density, electron temperature, ion flux, and ion energy. It is known that there is a direct correlation, and in particular, plasma density and plasma uniformity are closely related to throughput.

On the other hand, in the process of producing semiconductor chips, it is necessary to perform microfabrication in large quantities. A general plasma etching reactor may form various holes or grooves having a micrometer or nanometer scale in a substrate. Combined with other processes such as chemical vapor deposition and the like, several types of semiconductor chip products can be finally produced.

As technology advances, applications and demands for high aspect ratio etching are increasing. For example, in the field of memory, 3D NAND flash memory is one of the main structures of memory chips. In the process of manufacturing a 3D NAND chip, first, silicon oxide layers and silicon nitride layers are alternately stacked and formed (the number of layers may be 64 layers or even 100 layers or more), and all of the layers may be penetrated by plasma etching. Since the overall thickness of the layers is very large (greater than 5 μm or even greater than 8 μm), it belongs to a high aspect ratio etch. However, since an RF energy control system in a conventional plasma etching reactor cannot drive ions to the bottom of a hole in a layer to be etched, it is impossible to perform etching to form a hole.

In general, the depth of a hole or trench that can be formed during an etching process of an insulating material depends primarily on the depth accessible to ions in the plasma. In high aspect ratio (>40) etch processes, there can always be “ion-limited” process intervals. This means that the energy of the ions themselves is limited after passing through the sheath, and also the electric field formed by the charges accumulated on the sidewalls of the deep hole exerts a repulsive force on the ions so that the number of ions reaching the bottom of the hole is much reduced with the increase of the etched depth. or, even if the ions reach the bottom of the hole, their energy is not sufficient to continue etching the bottom material with the etchant (activator), so that the process requirements according to the depth of the hole cannot be satisfied.

On the other hand, the ultra-high aspect ratio etching process using plasma increases production cost, manufacturing process, and cycle time due to long process time. In order to overcome this situation, research is being conducted on methods of increasing the selectivity of the etching process by increasing the amount of a gas forming a polymer. However, in this method, etching may be stopped due to excessive polymer formation, and since formed polymers are non-uniformly deposited on the sidewall, an incident path of ions may be changed and an etching profile may be distorted.

Ultra-high aspect ratio structures are often achieved by etching away silicon oxide using a plasma containing carbon and fluorine. When plasma is generated using a continuous wave, if a large amount of dissociation of the reactive gas in the plasma occurs, excessive polymer formation may cause an etch stop, and it may be deposited non-uniformly on the sidewall to hinder the incident path of ions, resulting in necking ( This causes distortion of the etching profile, such as necking, bowing, and twisting. In order to remove unnecessarily formed polymers, there may be a method of suppressing the formation of polymers by reducing the density of active species, but this reduces the amount of active species reaching the high aspect ratio trench while maintaining the passivation layer. becomes difficult, making etching with an extremely high aspect ratio impossible. Therefore, for ultra-high aspect ratio etching, it is necessary to remove excessively attached polymers by physical impact through high-energy ions rather than reducing the density of active species. To this end, a method of controlling the energy of ions while maintaining the density of active species is required.

Korean Patent Registration [10-1047318] discloses an etching device using high frequency and an etching method using the same.

Korean Patent Registration [10-1939481] discloses an ion beam etching device.

Korean Patent Publication [10-2020-0089342] discloses geometrically selective deposition of dielectric films using a low-frequency bias.

Korean Patent Publication [10-2020-0096731] discloses a plasma reactor for high aspect ratio etching and an etching method thereof.

Korean Registered Patent [10-1047318] (registration date: 2011. 07. 01) Korean Registered Patent [10-1939481] (registration date: 2019. 01. 10) Korean Patent Publication [10-2020-0089342] (published date: 2020. 07. 24) Korean Patent Publication [10-2020-0096731] (published date: 2020. 08. 13)

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to apply a high frequency pulse to a source electrode of a plasma device and to apply a high frequency pulse to a bias electrode of the plasma device. By applying a low-frequency pulse only during the etching process, the density of active species is controlled and at the same time, the density of ions and the energy of ions reaching the substrate are independently controlled to maintain the critical dimension of the mask during the etching process. It is to provide a plasma ultra-high aspect ratio etching method using a high frequency pulse source capable of ultra high aspect ratio etching and a low frequency pulse bias.

Objects of the embodiments of the present invention are not limited to the above-mentioned purposes, and other objects not mentioned above will be clearly understood by those skilled in the art from the description below. .

To achieve the above object, a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to an embodiment of the present invention includes a loading step of loading a substrate to be processed onto a bias electrode (S810); a gas injection step of injecting an etching reaction gas (S820); A power application step (S830) of applying high-frequency source power to a source electrode inside the reaction chamber to form plasma and applying low-frequency bias power to the bias electrode inside the reaction chamber to control ion energy; Plasma generation step (S840) in which plasma is generated; and an etching step (S850) of etching the surface of the substrate using the generated plasma.

The power applying step (S830) may include periodically increasing and decreasing the density of active species by applying pulse-modulated high-frequency source power in which an on-period and an off-period are repeated to the source electrode; and inactivating and activating ion energy by applying the low-frequency bias power in which the off-period and the on-period are repeated synchronized to correspond to the on-period and off-period of the source power to the bias electrode.

The power applying step (S830) may include periodically increasing and decreasing the density of active species by applying pulse-modulated high-frequency source power in which an on-period and an off-period are repeated to the source electrode; and activating ion energy by applying low-frequency bias power to the bias electrode within an off period of the source power.

The high frequency source signal applied to the source electrode may have a frequency of 13.56 MHz, and the low frequency bias signal applied to the bias electrode may have a frequency of 400 kHz or 2 MHz lower than 13.56 MHz.

The high-frequency source signal applied to the source electrode and the low-frequency bias signal applied to the bias electrode are controlled to independently control the density of active species, the density of ions, and the energy level of ions reaching the substrate. .

Since the density of electrons and ions in the reaction chamber is proportional to the duty ratio of the high frequency source signal, the average density of active species is proportional to the duty ratio of the high frequency source signal.

Since the density of electrons and ions in the reaction chamber is proportional to the pulse frequency of the high frequency source signal, the average density of active species is proportional to the pulse frequency of the high frequency source signal.

The ion energy distribution function in the reaction chamber is characterized in that, as the frequency of the low-frequency bias signal increases, the energy of the ions is determined by the average voltage of the sheath generated near the bias, and the low-frequency bias signal As the frequency of the bias signal is lowered, the energy of the ions is determined by the real-time changing voltage applied to the sheath.

In addition, according to an embodiment of the present invention, a computer-readable recording medium storing a program for implementing the plasma ultra-high aspect ratio etching method using the high-frequency pulse source and the low-frequency pulse bias is provided.

In addition, according to an embodiment of the present invention, a program stored in a computer readable recording medium is provided to implement the plasma ultra-high aspect ratio etching method using the high frequency pulse source and the low frequency pulse bias.

According to the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to an embodiment of the present invention, a high-frequency pulse is applied to a source electrode of a plasma device, and a high-frequency pulse is applied to a bias electrode of the plasma device. By applying a low-frequency pulse only while it is not being applied, the density of active species is controlled, and at the same time, the density of ions and the energy of ions reaching the substrate are independently controlled to maintain the critical dimension of the mask during the etching process and ions with high energy There is an effect that enables ultra-high aspect ratio etching by

In addition, according to the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to an embodiment of the present invention, it can be used as a core technology for developing next-generation memories such as 3D NAND flash, PRAM, and RRAM, and atomic layer etching process It is possible to improve the yield of micro-sized semiconductor processes such as

In addition, according to the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to an embodiment of the present invention, the micro-sized semiconductor process yield can be improved, so there is an effect that can overcome the limitations of next-generation semiconductor device processes.

1 is a block diagram of a plasma device in which a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention is performed.
2A is a view according to an embodiment for explaining a method of applying pulse power to a source electrode and a bias electrode in a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention;
Figure 2b is another embodiment for explaining a method of applying pulse power to a source electrode and a bias electrode in a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention.
FIG. 3A is a graph showing ion density and electron density over time of high-frequency pulse power applied to a source electrode of a plasma device.
3B is a graph showing electron temperature changes according to time variation of high frequency pulse power applied to a source electrode of a plasma device.
FIG. 4 illustrates changes in the density of active species and ions generated in the plasma and the energy of ions reaching the substrate during the on-period and off-period of the high-frequency pulse applied to the source electrode of the plasma device according to the embodiment of FIG. 2a. drawing to do.
FIG. 5A is a diagram showing electron density, ion density, and electron density according to time variation of high-frequency pulse power applied to the source electrode of a plasma device when the duty ratio is 25 in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention. A graph showing electron temperature changes.
5B shows electron density, ion density, and electron density as a function of time-varying high-frequency pulse power applied to the source electrode of the plasma device when the duty ratio is 50 in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention. A graph showing electron temperature changes.
5C shows electron density, ion density, and electron density according to time variation of high-frequency pulse power applied to the source electrode of the plasma device when the duty ratio is 75 in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention. A graph showing electron temperature changes.
FIG. 6A is a graph showing the electron density and ion density of high frequency pulse power applied to the source electrode of a plasma device over time when the pulse frequency is 5 kHz in the plasma ultra-high aspect ratio etching method using a high frequency pulse source and a low frequency pulse bias according to the present invention. A graph showing changes in density and electron temperature.
FIG. 6B shows the electron density and ion density according to the time variation of the high frequency pulse power applied to the source electrode of the plasma device when the pulse frequency is 10 kHz in the plasma ultra-high aspect ratio etching method using a high frequency pulse source and a low frequency pulse bias according to the present invention. A graph showing changes in density and electron temperature.
FIG. 6C shows the electron density and ion density according to the time variation of the high frequency pulse power applied to the source electrode of the plasma device when the pulse frequency is 20 kHz in the plasma ultra-high aspect ratio etching method using a high frequency pulse source and a low frequency pulse bias according to the present invention. A graph showing changes in density and electron temperature.
7 is a graph showing an ion energy distribution function according to the frequency of low-frequency pulse power applied to a bias electrode in a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention.
8 is a flowchart of an embodiment of a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, or substitutes included in the spirit and scope of the present invention.

It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be.

On the other hand, when an element is referred to as “directly connected” or “directly connected” to another element, it should be understood that no other element exists in the middle.

Terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "include" or "have" are intended to designate that there is a feature, number, process, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, processes, operations, components, parts, or combinations thereof is not precluded.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings in the context of the related art, and unless explicitly defined in this application, they should not be interpreted in ideal or excessively formal meanings. don't

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to ordinary or dictionary meanings, and the inventor appropriately uses the concept of terms in order to explain his/her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical spirit of the present invention. In addition, unless there is another definition in the technical terms and scientific terms used, they have meanings commonly understood by those of ordinary skill in the art to which this invention belongs, and the gist of the present invention is described in the following description and accompanying drawings. Descriptions of well-known functions and configurations that may be unnecessarily obscure are omitted. The drawings introduced below are provided as examples to sufficiently convey the spirit of the present invention to those skilled in the art. Accordingly, the present invention may be embodied in other forms without being limited to the drawings presented below. Also, like reference numerals denote like elements throughout the specification. It should be noted that like elements in the drawings are indicated by like numerals wherever possible.

The present invention relates to an extremely high aspect ratio etching process using high frequency pulsed plasma and low frequency alternating current bias.

Pulsed plasma is an essential element for achieving an extremely high aspect ratio in a semiconductor etching process using a fluorocarbon precursor (PFC precursor), a liquid fluorocarbon precursor (L-PFC precursor), and the like. In order to have an extremely high aspect ratio, it is necessary to optimize the amount of polymer accumulated in the trench so that etching by ions occurs while maintaining the critical dimension of the mask.

The amount of active species generated can be controlled by controlling the dissociation rate of the reactive gas according to the amount of power applied to the source electrode.

If the amount of active species is too large, an etch stop may occur due to an excessive amount of polymer formed upon reaching the substrate. Conversely, if the amount of active species is too small, the higher the aspect ratio, the less the polymer in the trench can reach, making ultra-high aspect ratio etching impossible.

Therefore, a sufficient amount of polymer must be supplied so that it is delivered deep into the trench, and a process of removing the amount of polymer through ion bombardment must occur repeatedly so that only an appropriate amount of polymer is formed at the entrance of the trench.

To this end, in the present invention, a synchronized bias or source whose phase is opposite to the pulse period of the plasma source power is used to control the density of active species that form polymers using pulsed plasma and, together with this, to control the energy of ions required for etching. We propose an ultra-high aspect ratio etching process method using a bias that is activated only in the power-off period.

1 is a block diagram of a plasma apparatus in which a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention is performed.

Referring to FIG. 1 , a plasma device in which a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention is performed includes a pulse modulated source power generator 101, a source impedance matcher 102, and a source electrode. 103, a pulse modulated bias power generator 104, a bias impedance matcher 105, a bias electrode 106, a wafer (substrate) 107, and a plasma 108.

That is, the plasma device includes power devices 101 and 104 capable of applying pulse-shaped waveforms to the source electrode 103 and the bias electrode 106 provided in the capacitive coupling type chamber (reaction chamber), respectively, and impedance matching. Groups 102 and 105 are included.

A 13.56 MHz radio frequency (RF) power generator for high-density plasma generation may be used as the pulse modulated source power generator 101, and an AC power generator having a frequency lower than 13.56 MHz may be used as the pulse modulated bias power generator 104. can For example, the frequency of the low-frequency signal applied to the bias electrode 106 may be 400 kHz or 2 MHz.

2A is a diagram illustrating an embodiment of a method of applying pulse power to a source electrode and a bias electrode in a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention, and FIG. 2B is a diagram according to the present invention. It is a diagram of another embodiment for explaining a method of applying pulse power to a source electrode and a bias electrode in a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias.

Referring to FIG. 2A , RF pulse power is repeatedly applied to the source electrode 103 for an on duration and an off duration so that plasma is repeatedly generated and extinguished. At the same time, the bias electrode 106 is synchronized to maintain the on-period when the power of the source electrode 103 is in the off-period by using low-frequency AC power, and to maintain the off-period when the power of the source electrode 103 is in the on-period. do.

That is, the low-frequency bias power in which the off period and the on period are repeated in synchronization with corresponding to the on period and the off period of the source power is applied to the bias electrode.

Referring to FIG. 2B, RF pulse power is repeatedly applied to the source electrode 103 for an on duration and an off duration so that plasma is repeatedly generated and extinguished. At the same time, low-frequency bias power is applied to the bias electrode 106 only within the off-period of the source power to activate ion energy.

3A is a graph showing ion density and electron density over time of high frequency pulse power applied to a source electrode of a plasma device, and FIG. 3B is a graph showing electron temperature changes over time of high frequency pulse power applied to a source electrode of a plasma device. It is a graph that represents

Referring to FIGS. 3A and 3B , the density of ions and active species can be increased by increasing the ionization rate and dissociation rate of the process gas containing carbon and fluorine used in the process due to the increase in electron density in the ON period. In the off section, as the plasma is extinguished and the electron density and electron temperature are reduced, the ionization and dissociation reactions of the process gas are reduced, thereby reducing the generation of active species and ions. While active species diffuse with a velocity distribution dependent on the gas temperature, ions rapidly decrease as electrons rapidly decrease while moving at high speed by the electric field generated as light electrons diffuse into the wall. The decrease in ions increases the size of the thickness of the sheath formed around the plasma, and accordingly, the voltage applied to the sheath and the energy of ions reaching the substrate increase. In addition, distortion of the etching profile due to electrical effects can be reduced by removing charges accumulated on the mask.

FIG. 4 illustrates changes in the density of active species and ions generated in the plasma and the energy of ions reaching the substrate during the on-period and off-period of the high-frequency pulse applied to the source electrode of the plasma device according to the embodiment of FIG. 2a. It is a drawing for

Referring to FIGS. 3A, 3B, and 4, when the power applied to the source electrode 103 is on, plasma is generated and the generation of active species and ions from the reactive gas increases as electron density and electron temperature increase. do. When power applied to the source electrode 103 is in an off period, plasma is extinguished and electron density and electron temperature decrease. As a result, active species and ions decrease, but ions decrease faster than active species according to the decreasing rate of light electrons. At this time, when the power of the bias electrode is in an on state (on period), high energy can be applied to ions generated in a small amount, and through this, etching with an extremely high aspect ratio is possible while controlling the amount of polymer.

FIG. 5A is a diagram showing electron density, ion density, and electron density according to time variation of high-frequency pulse power applied to the source electrode of a plasma device when the duty ratio is 25 in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention. FIG. 5B is a graph showing a change in electron temperature, and FIG. 5B is a graph showing the time-varying variation of high-frequency pulse power applied to the source electrode of a plasma device when the duty ratio is 50 in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention. 5c is a graph showing changes in electron density, ion density, and electron temperature according to the present invention, and FIG. 5C is a case where the duty ratio is 75 in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention, the source electrode of the plasma device 6A is a graph showing changes in electron density, ion density, and electron temperature according to time-varying applied high-frequency pulse power, and FIG. 6a is a graph in which the pulse frequency is 5 In the case of kHz, it is a graph showing electron density, ion density, and electron temperature change over time of the high-frequency pulse power applied to the source electrode of the plasma device. FIG. 6B is a graph using a high-frequency pulse source and a low-frequency pulse bias according to the present invention. In the plasma ultra-high aspect ratio etching method, when the pulse frequency is 10 kHz, it is a graph showing changes in electron density, ion density, and electron temperature over time of the high-frequency pulse power applied to the source electrode of the plasma device, and FIG. When the pulse frequency is 20 kHz in the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the method, electron density, ion density, and electron temperature change according to the time variation of the high-frequency pulse power applied to the source electrode of the plasma device It is a graph that represents

Referring to FIGS. 5A to 5C and 6A to 6C , it can be seen that the density of active species and ions in the plasma can be controlled by controlling the duty ratio or pulse frequency of the source power applied to the source electrode 103 .

That is, since the average density of electrons changes according to the change in the duty ratio of the source power and the pulse frequency, the density of active species dissociated from the reactive gas also changes.

In the case of the duty ratio, it can be seen that the average density of active species also increases because the dissociation rate of the reactive gas increases as the average density of electrons increases as the duty ratio increases. Therefore, the duty ratio or pulse frequency of the source power applied to the source electrode 103 can be used as a control variable for the ultra-high aspect ratio etching method.

7 is a graph showing an ion energy distribution function according to the frequency of low frequency pulse power applied to a bias electrode in a plasma ultra-high aspect ratio etching method using a high frequency pulse source and a low frequency pulse bias according to the present invention.

Referring to FIG. 7 , when the frequency of the low-frequency bias power (power) applied to the bias electrode 106 is high, the energy of ions reaching the substrate is determined by the average voltage over time of the sheath generated near the bias, At lower frequencies, the ion energy is determined by the real-time changing voltage across the sheath. Since this change in ion energy can affect the etching rate, it is possible to control the ion energy according to the change in frequency.

8 is a flowchart of an embodiment of a plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias according to the present invention.

First, a substrate to be processed is loaded onto the bias electrode (S810).

Thereafter, an etching reaction gas is injected (S820).

Thereafter, high-frequency source power is applied to the source electrode inside the reaction chamber to form plasma, and low-frequency bias power is applied to the bias electrode inside the reaction chamber to control ion energy (S830).

Then, plasma is generated (S840).

Thereafter, the surface of the substrate is etched using the generated plasma (S850).

In one embodiment, in the power applying step (S830), the pulse-modulated high-frequency source power in which the on-period and off-period are repeated is applied to the source electrode to periodically increase and decrease the density of active species, and the source power Ion energy is deactivated and activated by applying the low-frequency bias power in which the off period and the on period are synchronized corresponding to the on period and the off period of , to the bias electrode.

Meanwhile, in another embodiment, in the power applying step (S830), pulse-modulated high-frequency source power in which an on-period and an off-period are repeated is applied to the source electrode to periodically increase and decrease the density of active species, Ion energy is activated by applying low-frequency bias power to the bias electrode only within the off-period of the source power.

The high frequency source signal applied to the source electrode has a frequency of 13.56 MHz, and the low frequency bias signal applied to the bias electrode has a frequency lower than 13.56 MHz, for example, has a frequency of 400 kHz or 2 MHz.

A high-frequency source signal applied to the source electrode and a low-frequency bias signal applied to the bias electrode are controlled to independently control the density of active species, the density of ions, and the level of energy of ions reaching the substrate.

Since the density of electrons and ions in the reaction chamber is proportional to the duty ratio of the high frequency source signal, the average density of active species is proportional to the duty ratio of the high frequency source signal.

Meanwhile, since the density of electrons and ions in the reaction chamber is proportional to the pulse frequency of the high frequency source signal, the average density of active species is proportional to the pulse frequency of the high frequency source signal.

On the other hand, in the ion energy distribution function in the reaction chamber, as the frequency of the low-frequency bias signal increases, the energy of the ions is determined by the average voltage of the sheath generated near the bias, and the low-frequency bias signal As the frequency of is lower, the energy of ions is determined by the real-time changing voltage applied to the sheath.

Although the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias has been described above, a program for implementing the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias is stored. Of course, a program stored in a computer readable recording medium and a computer readable recording medium for implementing a plasma ultra-high aspect ratio etching method using a high frequency pulse source and a low frequency pulse bias can also be implemented.

That is, the plasma ultra-high aspect ratio etching method using the above-described high-frequency pulse source and low-frequency pulse bias may be provided by being included in a computer-readable recording medium by tangibly implementing a program of instructions for implementing it. will be easily understandable. In other words, it may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable recording medium. The computer readable recording medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the computer-readable recording medium may be specially designed and configured for the present invention, or may be known and usable to those skilled in computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and floptical disks. Included are hardware devices specially configured to store and execute program instructions, such as magneto-optical media, and ROM, RAM, flash memory, USB memory, and the like. Examples of program instructions include high-level language codes that can be executed by a computer using an interpreter, as well as machine language codes such as those produced by a compiler. The hardware device may be configured to act as one or more software modules to perform the operations of the present invention and vice versa.

The present invention is not limited to the above embodiments, and the scope of application is diverse, and various modifications and implementations are possible without departing from the gist of the present invention claimed in the claims.

101: pulse modulation source power generator 102: source impedance matcher
103: source electrode 104: pulse modulation bias power generator
105: bias impedance matcher 106: bias electrode
107: wafer (substrate) 108: plasma
S810: loading step
S820: gas injection step
S830: power application step
S840: Plasma generation step
S850: Etching step

Claims (10)

In the plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias,
a loading step of loading the substrate to be processed onto the bias electrode (S810);
a gas injection step of injecting an etching reaction gas (S820);
A power application step (S830) of applying high-frequency source power to a source electrode inside the reaction chamber to form plasma and applying low-frequency bias power to the bias electrode inside the reaction chamber to control ion energy;
Plasma generation step (S840) in which plasma is generated; and
An etching step (S850) of etching the surface of the substrate using the generated plasma;
In the power application step (S830),
periodically increasing and decreasing the density of active species by applying pulse-modulated high-frequency source power in which an on-period and an off-period are repeated to the source electrode; and
activating ion energy by applying low-frequency bias power to the bias electrode within an off period of the source power;
Plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias comprising a.
According to claim 1,
In the power application step (S830),
periodically increasing and decreasing the density of active species by applying pulse-modulated high-frequency source power in which an on-period and an off-period are repeated to the source electrode; and
Deactivating and activating ion energy by applying the low-frequency bias power in which the off period and the on period are synchronized corresponding to the on period and the off period of the source power to the bias electrode
Plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, characterized in that it comprises a.
delete According to claim 1,
The high frequency source signal applied to the source electrode is characterized in that it has a frequency of 13.56 MHz,
Plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, characterized in that the low-frequency bias signal applied to the bias electrode has a frequency of 400 kHz or 2 MHz lower than 13.56 MHz.
According to claim 4,
By controlling the high-frequency source signal applied to the source electrode and the low-frequency bias signal applied to the bias electrode, the density of active species, the density of ions, and the energy level of ions reaching the substrate are independently controlled. Plasma ultra-high aspect ratio etching method using high-frequency pulse source and low-frequency pulse bias.
According to claim 5,
The density of electrons and ions in the reaction chamber are
Since it is proportional to the duty ratio of the high frequency source signal,
Plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, characterized in that the average density of active species is proportional to the duty ratio of the high-frequency source signal.
According to claim 5,
The density of electrons and ions in the reaction chamber are
Since it is proportional to the pulse frequency of the high frequency source signal,
Plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, characterized in that the average density of active species is proportional to the pulse frequency of the high-frequency source signal.
According to claim 5,
The ion energy distribution function in the reaction chamber is
Characterized in that, as the frequency of the low-frequency bias signal increases, the energy of the ions is determined by the average voltage of the sheath generated near the bias,
Plasma ultra-high aspect ratio etching method using a high-frequency pulse source and a low-frequency pulse bias, characterized in that the lower the frequency of the low-frequency bias signal, the energy of the ions is determined by the real-time changing voltage applied to the sheath.
A computer-readable recording medium storing a program for implementing a plasma ultra-high aspect ratio etching method using the high-frequency pulse source and the low-frequency pulse bias according to any one of claims 1, 2, and 4 to 8.
A program stored in a computer readable recording medium for implementing a plasma ultra-high aspect ratio etching method using the high frequency pulse source and the low frequency pulse bias according to any one of claims 1, 2, and 4 to 8.

Images