EP2032974A1

EP2032974A1 - Method and apparatus for optically characterizing the doping of a substrate

Info

Publication number: EP2032974A1
Application number: EP07803753A
Authority: EP
Inventors: Frank Torregrosa; Laurent Roux
Original assignee: Ion Beam Services SA
Current assignee: Ion Beam Services SA
Priority date: 2006-06-14
Filing date: 2007-06-14
Publication date: 2009-03-11
Also published as: US20100012031A1; WO2007144514A1; CN101501475A; KR20090028629A; FR2902575A1; FR2902575B1

Abstract

The invention relates to an optical characterization method that includes a step of evaluating the doping of a substrate (SUB) by means of a reflected beam coming from a light source, this method being carried out with an apparatus comprising: - this light source (LAS) for producing an incident beam (I) along an axis of incidence; - a first detector (DET1) for measuring the power of this reflected beam (R) along an axis of reflection, the axis of incidence and the axis of reflection intercepting at a measurement point and making a non-zero measurement angle (2T); and - a polarizer (POL) placed in the path of the incident beam (I). Furthermore the light source (LAS) is monochromatic. The invention also relates to an ion implanter equipped with this apparatus.

Description

Method and apparatus for optical characterization of the doping of a substrate

The present invention relates to a method and an apparatus for optical characterization of the doping of a substrate.

In the electron microscope, a common operation consists in doping with an active species certain zones of a substrate, silicon, for example. The problem then arises of controlling the concentration of the active species in the doped zone.

Doping is commonly done using an ion implanter. According to this technique, the implantation of a substrate consists in bombarding it with ions that are accelerated by means of an intense electric field. It goes without saying that the characterization of the doping during implantation can not be accomplished totally by an electrical measurement because this measurement would be disturbed by the presence of neutral dopants, the saturation effect due to the sputtering and the presence of electrons. secondary. Several solutions have been proposed for estimating the concentration of the dopant.

A first solution is to measure the square resistance of the zone using the method known to those skilled in the art as a four-point method. The measurement is possible only after annealing of the substrate if the doping has been performed by ion implantation. In addition, this solution is inapplicable when the layer has a very small thickness; the points passing through the layer, it is no longer the resistance of the doped zone but that of the substrate which is measured.

A second solution discussed in US 2005/0 140976 consists in studying the propagation of a thermal wave generated optically in the doped zone. This solution is practically useless when the area is very thin due to an extremely limited sensitivity.

A third solution uses the θllipsométrlθ and, although it has certain advantages over previous solutions, it is very complex to implement.

A fourth solution makes it possible to estimate doping by taking advantage of the fact that the refractive index of a sample, in other words its reflection coefficient, is a function of its dopant concentration. Thus, US 2002/080356 proposes to illuminate a polychromatic light sample with a beam having a normal incidence and to measure the reflected beam. The measurement is made not on the substrate but on a sample covered with a resin whose index varies greatly depending on the initial concentration. This is therefore an indirect method that supports all the limitations inherent in this type of method.

The document US 2005/0 140976 already cited thus combines a method

Ξ of thermal type with a reflectometry measurement in polychromatic light. But if the refractive index depends on the dopant concentration, II also depends on the wavelength. It follows that the accuracy of the measurement is affected.

Thus, US 6,417,515 proposes to illuminate the substrate in 0 monochromatic light and to perform a differential reflectivity measurement using a detector receiving a portion of the incident beam and a detector receiving the reflected beam. Here, variations of the refractive index as a function of the wavelength are thus avoided. However, since the doped zone is not optically isotropic, a relative uncertainty results in the estimation of the refractive index.

Furthermore, US 6727108 discloses a method of characterization using a relatively complex apparatus and, therefore, quite expensive. This apparatus comprises, in addition to a light source used for measuring the concentration of the dopant, an additional source of Intermittent excitation which is at the origin of the known limitations of this technique, even if only an undesired annealing of the measuring area. In addition, the light source is a xenon lamp which therefore has the inherent limitations of polychromatic sources.

The present invention thus relates to a method for optical characterization of the doping of a substantially improved substrate both in terms of accuracy and sensitivity, by means of a device of great simplicity.

According to the invention, an optical characterization method comprising a step of evaluating the doping of a substrate (SUB) by means of a reflected beam coming from a light source is carried out with an apparatus comprising:

• this light source to produce an Incident beam along an Incidence axis,

a first detector for measuring the power of this beam reflected along a reflection axis, these axes of incidence and reflection intersecting at a measurement point and forming a non-zero measuring angle,

a polarizer disposed in the path of the incident beam; in addition, the light source is monochromatic. The polarizer makes it possible to measure the reflectivity on an identified optical axis of the substrate.

Preferably, this polarizer is thus arranged that the incident beam is in transverse magnetic mode in the plane of incidence defined by the incident and reflected beams. In this configuration, the sensitivity of the meter is optimal.

In addition, the apparatus comprises a differential amplifier receiving as input a detection signal from the detector and a reference signal for producing a measurement signal. Advantageously, the reference signal comes from a reference supply delivering a predetermined voltage.

Indeed, when the light source is sufficiently stable, it is not necessary to use a differential measurement technique between the reflected beam and the incident beam. Alternatively, the apparatus comprising a second detector for measuring the power of the incident beam, the reference signal is derived from this second detector.

According to an additional feature of the invention, the apparatus being adapted to a silicon substrate provided to have a nominal doping, the wavelength of the light source corresponds to a relative maximum of reflectivity difference between the undoped substrate and the substrate having the nominal doping.

By way of example, the wavelength is included in one of the ranges of the set comprising the range 400-450 nanometers, the range 300-350 nanometers and the range 225-280 nanometers.

In addition, the angle of incidence being equal to half the measurement angle, this angle of incidence is the incidence of Brewster within plus or minus 5 degrees.

Again, this is to maximize the sensitivity of the device. The invention also relates to an Ionic implanter comprising an optical characterization apparatus as specified above. The present invention will now appear in greater detail in the context of the following description of exemplary embodiments given by way of illustration with reference to the appended figures which represent:

FIG. 1, a block diagram of a first embodiment of an optical characterization apparatus, and

- Figure 2, a block diagram of a second embodiment of an optical characterization apparatus.

The elements present in the two figures are assigned a single reference. With reference to FIG. 1, according to a first embodiment, an apparatus provided for optically characterizing a SUB substrate comprises a monochromatic LAS light source followed by a POL polarizer from which an Incident I beam which illuminates this substrate with an angle d 'incidence θ.

This incident beam I reaches the substrate SUB at a measuring point to generate a reflected beam R. The measurement angle formed by the incident beams I and reflected R is twice the angle of incidence θ, it being understood that the bisector of this measurement angle is perpendicular to the plane of the substrate

SUB.

A detector DET is arranged in the path of the reflected beam R in order to restore the power thereof by producing a detection signal V _d .

A differential amplifier AMP receives on its inputs on the one hand this detection signal V _d and on the other hand a reference signal VQ to produce on its output a measurement signal V _m . The origin of this reference signal will be explained later. The polariβθur POL makes it possible to stress the substrate along an identified optical axis. However, it is preferable to orient this polarizer so that the incident beam I is in magnetic transvβrse mode in the Incidence plane defined by incident beams I and reflected R. In this mode, at the incidence known as "Brewβter" , the reflection of the incident beam I is minimal. This particular angle of incidence is defined by the following expression where H ₁ and n ₂ respectively represent the refractive index of the transmission medium of the incident beam I and that of the substrate and where Re means real part:

It should be remembered now that the index of substrate n ₂ varies with its level of doping, so that the incidence of Brewster is not the same as for a doped substrate and for an undoped substrate.

Thus, by adopting an angle of incidence close to the incidence of Brewster, the power of the reflected beam R is very small, but, on the other hand, the variations of the reflection coefficient of the substrate SUB as a function of the refractive index are maximum.

It is therefore desirable to set the value of the angle of incidence in a range centered on the value of the Brewster Incidence either for an undoped substrate or for a substrate having the maximum doping that is to be characterized. . For undoped silicon at the wavelength of 405 nanometers, where the Brewster Incidence is 79.5 degrees. In this case, the recommended range is 74 to 84 degrees, which is a 5 degree excursion on either side of the center value.

It should also be recalled that, for a given angle of incidence, the reflectivity of a doped substrate relative to that of the undoped substrate as a function of the wavelength of the light source has a pseudo-periodic appearance with a succession of relative maxima.

It is therefore preferable to select a source that corresponds to one of these maximums, if not the highest of them.

Moreover, the optimal wavelength is also a function of the depth at which the dopant concentration is measured: the lower the depth, the shorter the wavelength. Three privileged ranges have been highlighted that extend, the first from 400 to 450 nanometers, the second from 300 to 350 nanometers and the third from 225 to 280 nanometers. Some lasers now have a very high stability over time. It follows that the power of the incident beam I varies very little. In this case, the reference signal VQ supplied to the amplifier AMP will be a reference voltage derived from a stabilized power supply (not shown in the figure). This reference voltage VQ will advantageously take the value of the detection signal V4 obtained following the illumination of an undoped substrate.

However, it may be necessary to avoid any power variations of the light source.

Thus, with reference to FIG. 2, according to a second embodiment, the optical characterization apparatus always comprises a LAS monochromatic light source followed by a POL polarizer from which an Incident I beam emits which illuminates this substrate with an angle incidence θ. As before, a first detector DET1 is arranged in the path of the reflected beam R in order to restore the power thereof by producing the detection signal V _d .

Similarly, the differential amplifier AMP receives on its inputs on the one hand this detection signal V ^ and on the other hand a reference signal VQ to produce on its output a measurement signal V _m .

Here, the origin of the reference signal is different. Indeed, an optical splitter SPL is interposed in the path of the incident beam I between the polarizer POL and the substrate SUB to deflect part of this beam towards a second detector DET2. In addition, an attenuator ATT is arranged between this separator SPL and the second detector DET2 which now produces the reference signal V ₀ .

The attenuator ATT has an attenuation coefficient such that the reference signal VQ substantially corresponds to the detection signal V <j obtained following the illumination of an undoped substrate. In this way, the two detectors

DET1, DET2 analyze luminous fluxes with similar characteristics,

However, it would be conceivable to replace the optical attenuator ATT by an electronic attenuator arranged downstream of the second detector. The apparatus described above can be used to perform a characterization of a doped substrate, in particular to map this substrate.

It can also be installed in situ, in an ion implanter, to control doping during implantation. The fittings required of the implanter are not more detailed because they are within the reach of the skilled person.

The embodiments of the invention presented above have been chosen in view of their concrete nature. However, it would not be possible to exhaustively list all the embodiments covered by this invention. In particular, any means described may be replaced by equivalent means without departing from the scope of the present invention.

Claims

1) Optical characterization method comprising a step of evaluating the doping of a substrate (SUB) by means of a reflected beam coming from a light source, this method being implemented with an apparatus comprising:

this light source (LAS) for producing an incident beam (I) along an axis of incidence,

a first detector (DET, DET1) for measuring the power of this reflected beam (R) along a reflection axis,

Iβsdits axes of incidence and reflection intersecting at a measurement point and forming a non-zero measurement angle (2θ),

a polarizer (POL) disposed on the path of said incident beam (I), characterized in that said light source (LAS) is monochromatic.

2) Method according to claim 1, characterized in that said polarizer (POL) is thus arranged that said incident beam (I) is in transverse magnetic mode in the plane of incidence defined by said O beams (incident I) and reflected ( R).

3) Method according to any one of claims 1 or 2, characterized in that said apparatus comprises a differential amplifier (AMP) receiving as inputs a detection signal (V _d ) from the first detector ddt (DET, DET1) and a reference signal (VQ) to produce a measurement signal (V _m ).

4) Method according to claim 3, characterized in that said reference signal (V ₀ ) is derived from a reference supply delivering a 0 predetermined voltage.

5) Method according to claim 3 characterized in that, said apparatus comprising a second detector (DET2) for measuring the power of said incident beam (I), said reference signal (VQ) is derived from this second detector (DET2). 6) Method according to any one of the preceding claims characterized in that, adapted to a silicon substrate (SUB) intended to have a nominal doping, the wavelength of said light source (LAS) corresponds to a relative maximum of Reflectivity difference between the undoped substrate and the substrate having said nominal doping.

7) Method according to claim 6, characterized in that said wavelength is in one of the ranges of the set comprising the range 400-450 nanometers, the range 300-350 nanometers and the range 225-2 280 nanometers .

8) Method according to any one of the preceding claims characterized in that, the angle of incidence (θ) being equal to half said measurement angle, this angle of incidence is worth the incidence of Brewster more or less 5 degrees.

9) Ionic implant, characterized in that it comprises an apparatus according to any one of the preceding claims.