KR102797729B1 - EUV Mask and EUV Pellicle Inspection Device - Google Patents

Abstract

The present invention relates to an EUV mask and EUV pellicle inspection device, and the inspection device uses EUV light as measurement light to inspect defects in an EUV mask or to inspect defects by measuring the reflectivity and transmittance of an EUV pellicle, the inspection device comprising: a laser source; a condenser lens for condensing laser light output from the laser source; a plasma reaction unit for generating EUV light through a plasma reaction from laser condensed through the condenser lens into EUV light; an EUV collector mirror for capturing the EUV light generated in the plasma reaction unit and transmitting it to a measurement target; a light detector for detecting the amount of EUV light by transmitting the central light of the EUV collector mirror through the through hole and detecting peripheral light that does not transmit through the through hole, a first detector for detecting light reflected from an EUV mask or an EUV pellicle corresponding to a measurement target by the central light (measurement light) passing through the hole of the light detector, and a second detector for detecting light reflected from an EUV mask or an EUV pellicle corresponding to a measurement target when the measurement target corresponds to an EUV pellicle. It comprises a second detector that detects light transmitted from the pellicle.

Description

EUV Mask and EUV Pellicle Inspection Device

The present invention relates to an EUV mask and EUV pellicle inspection device, and more specifically, to an EUV mask and EUV pellicle inspection device capable of simultaneously measuring an EUV mask and an EUV pellicle by applying a simplified optical system structure and a plurality of detectors.

Exposure is a very important process in semiconductor technology development. The era of applying EUV exposure technology with a wavelength of 13.5 nm has arrived, replacing the existing ArF exposure technology with a wavelength of 193 nm, and it has become possible to perform even more refined processes by utilizing the next-generation EUV exposure equipment.

EUV pellicle is a thin film that protects the EUV mask. It prevents the mask from being contaminated by defects during exposure, and is a very important material that can improve the pattern formation defect rate when forming a fine pattern. The transmittance and homogeneity of the transmittance of the protective film directly affect the semiconductor exposure yield. Therefore, controlling the transmittance quality of the EUV pellicle material is very important in the production management of the EUV pellicle.

In addition, the reflectivity of the EUV pellicle also needs to be managed because the light reflected from the EUV pellicle causes pattern errors in the overlapping exposure portion of the semiconductor wafer.

Transmittance and reflectivity quality control of EUV pellicles is performed through transmission/reflection measurement process management using EUV transmission and reflectivity measurement equipment.

In order for EUV masks to be smoothly applied to the mass production process, it is essential to manage the quality of EUV pellicles by measuring the transmittance and reflectivity of EUV pellicles, which are protective films of EUV masks, as in the case of ArF mass production technology. In order to implement such devices, unlike existing ArF transmittance measuring devices, it is necessary to develop a new transmission/reflection measuring device that applies EUV light and EUV optics.

The prior art uses an EUV light source of the LPP (laser produced plasma) method that generates EUV light by forming plasma by irradiating an ND:YAG Q-switched pulse laser on a metal target, and a monochromator consisting of an oblique incidence mirror, a grating, and a slit is used to irradiate the EUV monochromatic light on the sample, and a beam splitter is used to divide the EUV light into reflected light and transmitted light, the reflected light is detected to form a reference signal for monitoring the variation of the light source, the transmitted light is reflected from the mask sample and formed into a sample reflection signal in the detector, and the device measures the reflectivity of the sample, which is the mask, using the reference signal and the sample reflection signal.

Another conventional measuring device uses an EUV lamp as a light source, applies an ML spectral filter and an SPF to irradiate only monochromatic EUV light to an EUV pellicle, detects the amount of light with two photo sensors that measure reflection and transmittance, and measures the transmittance and reflectance of an EUV pellicle by measuring transmission and reflection signals according to the presence or absence of a sample.

These existing conventional technologies have a problem in that the IR light from the EUV light source is not removed and is irradiated onto the sample, resulting in very low measurement precision. For this reason, it is very difficult to manufacture high-performance EUV masks and pellicles, which in turn results in problems such as reduced production yields.

In order to solve these problems, the present applicant has applied for a transmittance or reflectance measuring device using EUV light, comprising: a high-order harmonic EUV light source; an ML (Multi Layer) mirror unit having a multilayer film for selecting and reflecting only light of an arbitrary wavelength from light output from the EUV light source; a transmitted light measuring sensor for measuring the light transmitted through the object to be measured after the reflected light having an arbitrary wavelength is used as measurement light by irradiating the object to be measured; and a reflected light measuring sensor for measuring the light reflected from the object to be measured, thereby measuring the transmittance or reflectance of the object to be measured, and having a compensation means for compensating for changes in the output of the light output from the EUV light source.

However, the inspection device configured as above has a somewhat complicated optical system, which increases costs, makes the equipment manufacturing process difficult, and causes difficulties in arranging the optical system.

US 6864490 KR 10-2020-00121546 KR 10-2020-00121545 US 2015-0002925 US 7,738,135 KR 10-1370203

The purpose of the present invention to solve the above problems is to provide a high-performance inspection device capable of simultaneously inspecting an EUV mask and an EUV pellicle, with reduced production costs, easy device control, and a simplified optical system structure of an EUV mask or EUV pellicle inspection device.

In addition, the present invention aims to provide an EUV light source device having a simplified structure by improving the structure of a gas jet for applying a plasma reaction unit to generate an EUV light source of superior quality, thereby resolving the complexity of the existing complex structural design and the system applied thereto.

In order to achieve the above object, the present invention provides an inspection device that uses EUV light as a measurement light to inspect a defect in an EUV mask or to inspect a defect by measuring the reflectivity and transmittance of an EUV pellicle, the inspection device comprising: a laser source; a focusing lens that focuses a laser output from the laser source; a plasma reaction unit that generates the laser focused through the focusing lens into EUV light through a plasma reaction, an EUV collector mirror that collects the EUV light generated in the plasma reaction unit and transmits it to a measurement target; a light detector that detects the amount of EUV light by transmitting the central light of the EUV collector mirror through the through hole and detecting the peripheral light that does not transmit through the through hole while detecting the peripheral light, the central light (measurement light) passing through the hole of the light detector, reflected from an EUV mask or an EUV pellicle corresponding to a measurement target, and, if the measurement target corresponds to an EUV pellicle, transmitting the transmitted light from the EUV pellicle It is composed of a second detector that detects.

In addition, the EUV collector mirror is a collector having a reflection characteristic of an incident angle of EUV light incident from the plasma reaction section of less than <10 degrees, and is characterized by providing light to a sample while minimizing loss due to polarization of the EUV light.

In addition, the plasma reaction unit comprises a gas jet nozzle for supplying a plasma reaction gas to a laser focused by the focusing lens to generate EUV light, and a gas supply device for supplying the reaction gas to the gas jet nozzle from the outside, and the gas jet nozzle comprises a gas injection unit formed on one side of the gas jet nozzle body for receiving and injecting a plasma reaction gas from the gas supply device, and an injection means for injecting the gas injected into the gas injection unit to a plasma reaction target, so that the gas is concentrated at the center of the light transmitted through the focusing lens.

In addition, the injection means is configured with a first transport path having a cross-sectional structure that is connected to the gas injection portion and expanded to an arbitrary length, and a second transport path for generating a shock wave for the plasma reaction gas supplied from the first transport path.

In addition, the gas jet nozzle injects gas injected through the gas injection portion toward the center of the injection direction of the gas jet nozzle through the first transport path and the second transport path.

In addition, the first transport path is characterized by having a circular structure in cross section.

In addition, the gas jet nozzle is configured with a first transport path having a longitudinal cross-section structure expanded by an arbitrary length from a gas injection portion that receives plasma reaction gas from the gas supply device, and a second transport path having a longitudinal cross-section structure horizontal by an arbitrary length that extends from an end of the first transport path to generate a shock wave.

In addition, the photodetector is characterized in that a through hole is formed in the center for passing the central light of the light reflected from the EUV collector mirror, and a detection unit having a predetermined detection surface is formed while surrounding the through hole for measuring the remaining peripheral light excluding the central light.

Furthermore, when the center line of the incident light (210) incident on the EUV collector mirror is referred to as 'C1' and the center line of the reflected light (211) reflected by the incident light (210) is referred to as 'C2', the internal angle between 'C1' and 'C2' is 10 to 70 degrees.

In addition, since the EUV collector mirror and the photodetector are arranged so that the center line 'C2' of the reflected light (211) reflected from the EUV collector mirror passes through the through hole (300) of the photodetector, no separate mirror for changing the optical path is provided between the EUV collector mirror and the photodetector, thereby preventing loss of optical energy.

In addition, the photodetector is characterized in that it controls the gas injection amount of the gas supply device to control the amount of EUV light generated in the plasma reaction unit based on the light amount information of the EUV light obtained from the detection unit.

The present invention, configured and operated as described above, can provide an inspection device having a simplified optical system structure, and has the effect of providing an inspection device capable of simultaneously measuring pellicle transmittance and reflectivity for defect inspection of an EUV mask or inspection of an EUV pellicle.

Accordingly, the present invention can be applied to various semiconductor processes or devices that require EUV light, and in particular, has the effect of improving inspection performance by applying it to EUV mask, EUV blank mask, and EUV pellicle defect inspection devices through generation of excellent quality EUV light.

In addition, the present invention has the advantage of being able to provide a reaction gas for plasma reaction at a high density to a reaction target in a light source device generating EUV light, thereby generating excellent EUV light, and providing an EUV light source device with a simplified system by only changing the structure of the gas jet.

In addition, the present invention has the effect of improving inspection performance by applying it to EUV mask, blank mask, and pellicle defect inspection devices through generation of excellent quality EUV light.

Figure 1 is a diagram showing the overall configuration of an EUV mask and EUV pellicle inspection device according to the present invention.
Figure 2 is a detailed view of the photodetector of the EUV mask and EUV pellicle inspection device according to the present invention.
Figure 3 is a detailed drawing of a plasma reaction unit applied to an EUV mask and EUV pellicle inspection device according to the present invention.
Fig. 4 is a detailed drawing of a gas jet nozzle configured in a plasma reaction unit according to Fig. 3.
Figure 5 is a detailed diagram showing the arrangement relationship between incident light and reflected light.

Hereinafter, the EUV mask and EUV pellicle inspection device according to the present invention will be described in detail with reference to the attached drawings.

The EUV mask and EUV pellicle inspection device according to the present invention is an inspection device that uses EUV light as measurement light to inspect defects in an EUV mask or to inspect defects by measuring the reflectivity and transmittance of an EUV pellicle, the inspection device comprising: a laser source, a collecting lens that collects laser light output from the laser source, a plasma reaction unit for generating EUV light through a plasma reaction from laser collected through the collecting lens, an EUV collector mirror that collects the EUV light generated in the plasma reaction unit and transmits it to a measurement target, a light detector that detects the amount of EUV light by transmitting the central light of the EUV collector mirror through the through hole and detecting peripheral light that does not transmit through the through hole, a first detector that detects light reflected from an EUV mask or EUV pellicle corresponding to a measurement target by the central light (measurement light) passing through the hole of the light detector, and if the measurement target corresponds to an EUV pellicle, a first detector that detects light reflected from the EUV pellicle corresponding to the measurement target. It comprises a second detector that detects transmitted light.

The EUV mask and EUV pellicle inspection device according to the present invention has a technical purpose of simultaneously measuring defects in an EUV mask and an EUV pellicle by simplifying the structure of an optical system and applying a plurality of detectors, and of generating EUV light of superior quality through technical improvement of a plasma reaction unit, thereby providing an inspection device optimized for defect inspection.

Therefore, an inspection device using EUV light provides an EUV inspection device that can improve inspection performance as a result of process improvement by applying high-quality EUV light in EUV blank mask, EUV mask, and EUV pellicle defect inspection processes.

Figure 1 is a diagram showing the overall configuration of an EUV mask and EUV pellicle inspection device according to the present invention.

EUV light in the high-harmonic mode can be generated by irradiating a laser (ex. Nd:YAG laser) with a pulse width of tens to hundreds of femtoseconds to an inert gas (plasma reaction gas) formed in a local area inside a vacuum device, and Ne (Neon) and He (Helium) are known to be suitable for generating EUV light. With the growth of semiconductor integration technology, EUV light is being widely used in semiconductor processes, and is especially essential in exposure processes and inspection processes.

Accordingly, in order to develop a device for inspecting defects in an EUV mask or an EUV pellicle using EUV light, the present invention simplifies the structure of an optical system to minimize light loss, improves the accuracy of defect inspection through excellent EUV light source generation, and provides an inspection device capable of simultaneously inspecting an EUV mask and a pellicle in one device.

As shown in the overall configuration diagram of Fig. 1, it includes one laser source (ex. Nd:YAG laser; 100) for outputting a source laser for generating EUV light, a focusing lens (100) for focusing the light of the laser source, a plasma reaction unit (120) for generating EUV light through plasma reaction of the focused laser, an EUV collector mirror (200) for reflecting the EUV light generated in the plasma reaction unit, and a plurality of detectors for detecting light reflected or transmitted from a measurement target (A).

In the present invention, the performance of an inspection device utilizing EUV light is greatly improved through excellent EUV light generation through the plasma reaction unit, simplification of the optical system structure that directly irradiates measurement light to a measurement target through an EUV collector mirror, and measurement function of reflected light and transmitted light through multiple detectors.

The light output from the laser source (100) is monochromatic light, and it is preferable to use coherent EUV light with excellent spatial coherence. According to experimental experience and literature, all of the light generated from each of the above devices can be applied, but the light source suitable for industry is an EUV light source of the high-harmonic wave method.

The light output from the above laser source (100) is incident on the EUV collector mirror (200) and then reflected again. In the case of various existing inspection devices, the light is structured to be reflected several times through multiple optical mirrors, but in the present invention, only one EUV collector mirror optical system is used so that the EUV light generated in the plasma reaction section is directly incident on the measurement target (A).

At this time, the EUV collector mirror (200) is a mirror having optical characteristics of an incident angle of less than <10 degrees, and collects light provided from the plasma reaction section to minimize light loss and provide it as a measurement target.

The light reflected from the EUV collector mirror (200) passes through a photodetector (300) and is provided to the measurement target (A). The photodetector has a hole in the center and a detection surface that detects the remaining peripheral light while allowing the central light from the light reflected from the collector mirror to pass through is configured to face the incident direction. The detection surface of the photodetector (300) measures the amount of EUV light incident through the EUV collector mirror (200), and the central light passes through the hole at the center of the photodetector and is irradiated to the measurement target. The photodetector (300) is described in detail in FIG. 2 below.

The measurement light passing through the above-mentioned photodetector is directly irradiated onto the measurement target (A), and here, two detectors, a first detector (400) and a second detector (500), are configured respectively to measure only the reflected light or simultaneously measure the reflected light and transmitted light depending on the measurement target.

In the case of the measurement target (A) being an EUV mask, only reflected light is acquired and the first detector (400) is used to acquire reflected light in order to detect defects in the mask, and in the case of an EUV pellicle, both reflected light and transmitted light must be measured. Therefore, the reflected light is measured by the first detector (400), and the second detector (500) is configured at the lower part in the transmission direction of the measurement target to detect transmitted light, thereby enabling detection of defect information according to the amount of reflectivity/transmittance light.

Therefore, as described above, the present invention can simplify the optical system by capturing EUV light generated from a plasma reaction through one EUV collector mirror and directly irradiating it onto a measurement target to obtain image information, and can simultaneously measure reflected light and transmitted light by configuring the first detector (400) and the second detector (500), respectively, so that the measurement target can be scanned at high speed.

FIG. 2 is a detailed diagram of a photodetector of an EUV mask and EUV pellicle inspection device according to the present invention.

As described above, the photodetector (300) is structurally provided with a hole in the center so that the central light of the light captured by the collector mirror (200) is irradiated to the measurement target as the measurement light, and the detection unit (320) is configured to measure the amount of light by measuring the peripheral light other than the central light.

As shown, (a) is a side view drawing of a photodetector, and (b) is a plan view drawing. When viewed in the plan view drawing, a through hole (310) is formed through which central light can pass, and a detection unit (320) having a structure surrounding the through hole is provided, forming one photodetector (300).

The above penetration hole (310) allows only the central light of the light reflected from the EUV collector mirror (200) to pass through and be used as measurement light, and the surrounding light can be detected by the detection unit (320) to obtain light quantity information of the reflected light. The light quantity information obtained here can be fed back by applying it to EUV light generation information according to light quantity change or defect information value of the measurement target, and can be applied as a reference signal to control the output light.

In addition, as a major technical feature of the present invention, in order to generate excellent EUV light, the amount of EUV light through the plasma reaction unit described below can be precisely measured by the photodetector to control the generation of the amount of light, and based on the detected amount of light information, the amount of gas injected or the injection speed of the gas injection device configured in the plasma reaction unit can be controlled to determine the amount of light generated. The gas injection device is described below.

Figure 3 is a detailed drawing of a plasma reaction unit applied to an EUV mask and EUV pellicle inspection device according to the present invention. The plasma reaction unit (120) of the present invention can correspond to one EUV light source device that can generate EUV light of excellent quality as a result by applying a spraying means of a gas jet nozzle (121) to induce a high-density reaction through plasma reaction gas.

In order to configure the above EUV light source device, it is composed of a plasma reaction unit (120) including one laser source (100), one focusing lens (110) for focusing light output from the laser source, and a gas jet nozzle (121) for providing plasma reaction gas to obtain EUV light through a gas focusing type plasma reaction.

At this time, in the present invention, the structure of the gas jet nozzle (121) is improved through an injection means that injects plasma reaction gas, thereby generating EUV light by irradiating a focused laser to a high-density localized target. Preferably, the gas jet nozzle (121) according to the present invention is characterized by having a structure that generates a shock wave.

The present invention is to generate EUV light using a gas jet nozzle that generates shock waves, and can generate high-quality EUV light through a very simplified structure that is free from the complex gas jet structure of the past, thereby enabling high-resolution processing in defect inspection or exposure equipment.

Accordingly, the EUV light source device according to the present invention is composed of a laser source (100) that outputs laser light, a focusing lens (110) that focuses the light output from the laser source, and a gas jet nozzle (121) that generates EUV light through plasma reaction. The gas jet nozzle (200) will be described in detail with reference to FIG. 3 below.

Fig. 4 is a detailed drawing of a gas jet nozzle configured in a plasma reaction unit according to Fig. 3.

The EUV light source device according to the present invention adopts a gas jet supply method among various conventional gas supply methods for generating EUV light through a gas reaction by supplying a plasma reaction gas, and proposes a structure of a gas jet nozzle as shown in FIG. 2.

Specifically, the gas jet nozzle (121) comprises a gas jet nozzle body (122), a gas injection part (123) for receiving gas from an external gas supply device, and an injection means (transport path) communicating with the gas injection part and for spraying the injected gas. At this time, the transport paths are composed of a first transport path (124) and a second transport path (125), which correspond to injection means for concentrating gas toward the center to generate shock waves.

Here, a shock wave of plasma reaction gas is generated through the first transfer path (124) and the second transfer path (125), which are the injection means, to achieve another technical objective of the present invention. Specifically, it is composed of the first transfer path (124) having a longitudinal cross-section structure expanded by an arbitrary length (h2) from the gas injection portion (123), and the second transfer path (125) having a longitudinal cross-section structure that extends from the end of the first transfer path (124) and is horizontal by an arbitrary length (h1), and the first transfer path primarily diffuses the injected gas, and then increases the pressure by reducing the transfer area through the second transfer path (125), thereby controlling the direction and pressure of the gas to generate a shock wave.

In addition, it is preferable that the first transport path (124) and the second transport path (125) have a circular structure in cross section, and the first transport path is configured to be longer than the second transport path so that the pressure of the transport gas can be determined as a result.

Figure 5 is a drawing showing the arrangement relationship between incident light (210) and reflected light (211).

When the center line of the incident light (210) incident on the EUV collector mirror is referred to as 'C1' and the center line of the reflected light (211) reflected by the incident light (210) is referred to as 'C2', the internal angle between 'C1' and 'C2' is 10 to 70 degrees.

At this time, when a virtual center line 'C' is created perpendicular to the reflection surface from the center of the EUV collector mirror (200), the internal angles of 'C1' and 'C' and the internal angles of 'C2' and 'C' may be the same or different.

In addition, since the EUV collector mirror and the photodetector are arranged so that the center line 'C2' of the reflected light (211) reflected from the EUV collector mirror passes through the through hole (300) of the photodetector, no separate mirror for changing the optical path is provided between the EUV collector mirror and the photodetector, thereby preventing loss of optical energy.

In this way, a clear and sharp image can be obtained during defect inspection of an EUV mask or inspection of an EUV pellicle without using an optical path changing means (e.g., a mirror, etc.) between the EUV collector mirror (200) and the measurement object.

The present invention, configured as described above, can provide an inspection device having a simplified optical system structure, and has the effect of providing an inspection device capable of simultaneously measuring pellicle transmittance and reflectivity for defect inspection of an EUV mask or inspection of an EUV pellicle.

Accordingly, the present invention can be applied to various semiconductor processes or devices that require EUV light, and in particular, has the effect of improving inspection performance by applying it to EUV mask, EUV blank mask, and EUV pellicle defect inspection devices through generation of excellent quality EUV light.

In addition, the present invention has the advantage of being able to provide a reaction gas for plasma reaction at a high density to a reaction target in a light source device generating EUV light, thereby generating excellent EUV light, and providing an EUV light source device with a simplified system by only changing the structure of the gas jet.

While the present invention has been described and illustrated with reference to preferred embodiments for illustrating the principles of the present invention, it is not intended to be limited to the exact construction and operation as described and illustrated. Rather, it will be readily apparent to those skilled in the art that numerous changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such appropriate changes and modifications and equivalents should also be considered to fall within the scope of the present invention.

100 : Laser source 110 : Concentrator lens
120: Plasma reaction section 121: Gas jet nozzle
122: Gas jet nozzle body 123: Gas injection part
124: 1st transfer route 125: 2nd transfer route
130 : Gas supply device 200 : EUV collector mirror
300 : Photodetector 310 : Through hole
320: Detector 400: 1st detector
500: 2nd detector A: Measurement target

Claims (7)

In an inspection device that uses EUV light as a measuring light to inspect defects in an EUV mask or to inspect defects by measuring the reflectivity and transmittance of an EUV pellicle,
laser source;
A single focusing lens for focusing the laser beam output from the laser source;
A plasma reaction unit for generating EUV light through plasma reaction from laser light collected through the above-mentioned collecting lens;
An EUV collector mirror that captures EUV light generated in the plasma reaction section and transmits it to a measurement target;
A photodetector having a through hole through which EUV light passes through the center, transmitting the central light of the EUV collector mirror through the through hole and detecting peripheral light that does not pass through the through hole to detect the amount of EUV light;
A first detector that detects light reflected from an EUV mask or EUV pellicle corresponding to a measurement target from the central light (measurement light) passing through the hole of the above photodetector; and
An EUV mask and EUV pellicle inspection device comprising a second detector for detecting light transmitted from an EUV pellicle when the above measurement target corresponds to an EUV pellicle. In the first paragraph, the EUV collector mirror,
An EUV mask and EUV pellicle inspection device characterized in that the collector has a reflection characteristic in which the incident angle of EUV light incident from the plasma reaction section is less than 10 degrees, and provides light to a sample while minimizing loss due to polarization of the EUV light. In the first paragraph, the plasma reaction unit,
A gas jet nozzle for generating EUV light by supplying plasma reaction gas to the laser focused by the above focusing lens; and
An EUV light source device is configured, including a gas supply device that supplies a reaction gas to the gas jet nozzle from the outside;
An EUV mask and EUV pellicle inspection device, wherein the gas jet nozzle comprises a gas injection unit formed on one side of the gas jet nozzle body for receiving and injecting plasma reaction gas from the gas supply device, and an injection means for injecting the gas injected into the gas injection unit toward the plasma reaction target, so that the gas is concentrated at the center of the light passing through the collecting lens. In the third paragraph, the injection means,
An EUV mask and EUV pellicle inspection device, each comprising a first transport path having a cross-sectional structure expanded to an arbitrary length and communicating with the gas injection portion, and a second transport path for generating a shock wave for plasma reaction gas supplied from the first transport path. delete delete delete