JP2008235726A - Manufacturing method of semiconductor multilayer film - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress the generation of a leakage current accompanying the deterioration of crystallinity on respective layer interfaces of a collector and a base and an emitter and the base in a semiconductor multilayer film, for instance the semiconductor multilayer film for which respective semiconductor layers to be used for the collector, the base and the emitter are continuously formed by epitaxial growth. <P>SOLUTION: For instance, when continuously forming the respective semiconductor layers to be used for the collector (a first of a first conductivity-type single crystal layer), the base (a second conductivity-type single crystal layer) and the emitter (a second of the first conductivity-type single crystal layer) without exposing them to the atmosphere, the respective semiconductor layers to be used for the collector and the emitter are epitaxially grown in a reduced pressure state, and the semiconductor layer to be used for the base is epitaxially grown in a high vacuum state. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a method for manufacturing a semiconductor multilayer film. The present invention is particularly useful when applied to a method of manufacturing a bipolar transistor in which a collector layer, a base layer, and an emitter layer are formed by epitaxial growth.

  A bipolar transistor in which a base layer and an emitter layer are formed by conventional epitaxial growth is reported in, for example, Japanese Patent Application Laid-Open No. 2003077784 (Patent Document 1).

  An example of a typical manufacturing method so far is as follows. On the silicon substrate, a high-concentration n-type buried layer and a low-concentration n-type silicon layer to be a collector region are formed, and then an element isolation insulating film and a high-concentration n-type region are formed. A trench-type element isolation region is usually formed between the transistors. Thereafter, a multilayer film of a collector / base isolation insulating film, a base lead-out polycrystalline silicon film, and an emitter / base isolation insulating film is deposited thereon. An emitter opening is formed in a region corresponding to the emitter region in the multilayer film, and a second emitter isolation insulating film is formed on the side walls of the emitter / base isolation insulating film and the base lead-out polycrystalline silicon film. Next, the collector / base isolation insulating film is selectively etched to form a base lead polycrystalline silicon film eaves. Thereafter, a low-concentration p-type single crystal silicon layer is formed on the surface of the low-concentration n-type silicon layer. Then, by selective growth again, an intrinsic base composed of a p-type single crystal silicon / germanium layer on the low-concentration p-type single crystal silicon layer, and a p-type polycrystalline silicon / germanium layer under the eaves of the base lead-out polycrystalline silicon A tether base consisting of Next, an emitter made of a single n-type crystal silicon layer is formed in the opening, and an insulating film and a polycrystalline silicon layer for separating a third emitter and base are deposited on the side wall of the opening. Thereafter, a polycrystalline n-type silicon layer to be an emitter electrode is formed, and an insulating film is deposited on the entire surface of the stacked body. An opening for contact is formed at a desired location of the multilayer laminate thus obtained, and each of a base electrode, an emitter electrode, and a collector electrode is formed.

Japanese Patent Laying-Open No. 2003077784 (FIG. 1)

FIG. 6 shows the distribution in the depth direction of the germanium composition ratio and impurity concentration in the intrinsic part of a typical bipolar transistor so far in which the base layer and the emitter layer are formed by epitaxial growth. The horizontal axis represents the depth from the surface, and the vertical axis represents the impurity concentration and the Ge composition ratio. Typically, on a semiconductor substrate, a collector made of a multilayer film of n-type single crystal silicon (n-Si) and low-concentration n-type single crystal silicon / germanium (n ⁻ -SiGe), and a p-type single crystal silicon / germanium layer ( A base layer made of p-SiGe) and an emitter layer made of a high-concentration n-type single crystal silicon layer (n ⁺ -Si / SiGe) are sequentially formed by epitaxial growth using the LPCVD method. At this time, since the doping impurity and germanium cause segregation and mixing at the interface between the layers at a high growth temperature, the p-type impurity forming the base layer diffuses into the substrate (from p-SiGe to n in FIG. 6). ^The base width is (D2′−D1 ′), as seen in the impurity concentration of SiGe. This value becomes larger than the thickness of the p-type layer immediately after forming the p-type single crystal silicon / germanium layer, and the cutoff frequency of the bipolar transistor is lowered. The position of D2 ′ is a position where the n-type impurity concentration from the emitter side and the p-type impurity concentration from the base side are equivalent. Further, the n + Si region in FIG. 6 is a high concentration impurity region which is usually provided on the semiconductor substrate from a practical viewpoint.

  On the other hand, when the collector, base, and emitter layers are formed by epitaxial growth using the UHV / CVD method, the growth rate is slow, so that throughput is extremely deteriorated, and at the same time, the doping concentration of n-type impurities cannot be increased in the emitter layer. As the emitter resistance increases, the transistor characteristics deteriorate.

  In view of these facts, the object of the present invention is to manufacture a semiconductor multilayer film composed of a plurality of single crystal layers having different conductivity types, thereby suppressing blurring of impurity distribution in each layer of the multilayer film and enabling high-concentration doping. It is an object of the present invention to provide a method for forming a multilayer film.

  A method for forming a semiconductor multilayer film according to the present invention is as follows. That is, on the surface of the single crystal substrate, for example, on the first conductivity type region provided on the surface of the single crystal silicon substrate (that is, typically on the high concentration n-type buried region), the first first conductivity type is formed. Type single crystal layer (that is, typically an n-type single crystal silicon / germanium layer as a typical example) and a first conductivity type opposite to the first conductivity type provided on the first first conductivity type single crystal layer A second conductivity type single crystal layer (that is, a p-type single crystal silicon / germanium layer as a representative example) and a second first conductivity type single crystal layer (on the second conductivity type single crystal layer ( That is, as a typical example, a method for forming a semiconductor multilayer film made of an n-type single crystal silicon layer), wherein the single crystal substrate is always held in a hydrogen atmosphere or vacuum during the formation of the semiconductor multilayer film, The pressure for growing the p-type single crystal silicon / germanium layer is changed to the n-type single crystal. It is characterized in that lower than the pressure of growing silicon germanium layer and the n-type single crystal silicon layer.

  Alternatively, on the surface of the single crystal substrate, for example, on the first conductivity type region provided on the surface of the single crystal silicon substrate (that is, typically on the high-concentration n-type buried region), the first first A conductive single crystal layer (ie, typically an n-type single crystal silicon / germanium layer as a typical example) and a first conductive type opposite to the first conductive type provided on the first first conductive single crystal layer; A second conductivity type single crystal layer (that is, a p-type single crystal silicon / germanium layer as a representative example) and a second first conductivity type single crystal layer provided on the second conductivity type single crystal layer That is, a method for forming a semiconductor multilayer film composed of an n-type single crystal silicon layer, wherein the single crystal substrate is always held in a hydrogen atmosphere or vacuum during the formation of the semiconductor multilayer film, and the n-type single crystal silicon germanium Layer and the n-type single crystal silicon layer in the first growth chamber The p-type single crystal silicon / germanium layer is formed in the second growth chamber, and the pressure for growing the p-type single crystal silicon / germanium layer is adjusted to the n-type single crystal silicon / germanium layer and the n-type. The pressure is lower than the pressure for growing the single crystal silicon layer.

  Further, on the surface of the single crystal substrate, for example, on the first conductivity type region provided on the surface of the single crystal silicon substrate (that is, typically on the high-concentration n-type buried region), the first first A conductive single crystal layer (ie, typically an n-type single crystal silicon / germanium layer as a typical example) and a first conductive type opposite to the first conductive type provided on the first first conductive single crystal layer; A second conductivity type single crystal layer (that is, a p-type single crystal silicon / germanium layer as a representative example) and a second first conductivity type single crystal layer provided on the second conductivity type single crystal layer That is, a method for forming a semiconductor multilayer film composed of an n-type single crystal silicon layer, wherein the single crystal substrate is always held in a hydrogen atmosphere or vacuum during the formation of the semiconductor multilayer film, and the n-type single crystal silicon germanium A layer, the p-type single crystal silicon-germanium layer, and the layer The pressure for growing the p-type single crystal silicon / germanium layer is the same as the pressure for growing the n-type single crystal silicon / germanium layer and the n-type single crystal silicon layer. Lower than that.

  In each of the semiconductor multilayer film manufacturing methods described above, the first first conductivity type single crystal layer (for example, the n-type single crystal silicon / germanium layer) and the second first conductivity type single crystal layer (for example, The pressure for growing the n-type single crystal silicon layer) is preferably 100 Pa or more. In the method for producing each semiconductor multilayer film described above, the pressure for growing the second conductive single crystal layer (for example, the p-type single crystal silicon / germanium layer) is preferably 1 Pa or less.

  In the above description, in order to facilitate understanding of the present invention, examples of each semiconductor layer are shown in parentheses as examples of bipolar transistors as specific examples. However, the semiconductor multilayer film of the present invention is not limited to this.

  The present invention provides a method for forming a semiconductor multilayer film that can suppress impurity distribution in each layer of the multilayer film and can perform high-concentration doping when manufacturing a semiconductor multilayer film composed of a plurality of single crystal layers having different conductivity types. I can do it.

  In the practice of the present invention, representative semiconductor materials include the first first conductivity type single crystal layer, the second conductivity type single crystal layer, and the second first conductivity type single crystal layer. One member of the group is a semiconductor material containing silicon or germanium as a main component. These are extremely useful when applied to a bipolar transistor which is a typical application example. For example, the first first conductivity type single crystal layer is used as a collector region, the second conductivity type single crystal layer as a base region, and the second first conductivity type single crystal layer as an emitter region. Examples of the semiconductor material containing silicon or germanium as a main component are Si, Si—Ge based semiconductor material, and Ge. Further, SiC-based semiconductor materials or SiGeC-based semiconductor materials containing carbon (C) are also useful.

  A preferred embodiment of the method for forming a bipolar transistor according to the present invention is as follows. FIG. 7 is a cross-sectional view of a representative example of a semiconductor multilayer film which is a manufacturing method of the present invention. That is, on the high-concentration buried region 31 on the silicon substrate 30, a low-concentration collector 32, an intrinsic base layer 33 made of a single-crystal layer having a conductivity type opposite to the collector region, and a single-crystal layer having the same conductivity type as the collector region The emitter region 34 is continuously formed without being exposed to the atmosphere, and the intrinsic base is formed in a high vacuum state where the atmospheric pressure is 1 Pa or less, and the collector and the emitter are formed under atmospheric pressure. Is performed in a reduced pressure state of 100 Pa or more. Therefore, typically, the formation of the intrinsic base has a pressure difference of approximately two orders of magnitude or more between the atmospheric pressure and the formation of the collector and emitter by the atmospheric pressure. In this case, the flow rate of each gas is frequently several l / min for the carrier gas, for example, 10 l / min from 1 l / min, while the source gas is frequently used from about 1 cc / min to about 50 cc / min. The silicon substrate 30 provided with the high-concentration buried region 31 is prepared by a usual method in this technical field. In order to improve the characteristics of the semiconductor device more practically, other semiconductor layers can be inserted in addition to the high concentration buried region 31.

  Since the collector, the intrinsic base, and the emitter are continuously formed in this way, high temperature cleaning treatment is not required before epitaxial growth of the intrinsic base and emitter, and the spread of dopants caused by the heat treatment can be reduced, and the high-speed transistor Can be realized. Moreover, since the intrinsic base is grown in a high vacuum state with a pressure of 1 Pa or less, the germanium composition ratio, doping concentration, and film thickness can be controlled with high precision, so the internal electric field of the base is effectively generated to increase the speed. And the yield can be improved. Further, by epitaxially growing the collector and the emitter in a reduced pressure state of 100 Pa or more and atmospheric pressure, it is possible to reduce resistance by high concentration doping and improve throughput by high-speed growth. Therefore, the bipolar transistor according to the present invention can achieve both high speed operation and low cost.

  The pressure of the atmosphere for forming the intrinsic base (corresponding to the second conductivity type single crystal layer) is a high vacuum state of 1 Pa or less, but about 1 Pa or less and 0.1 Pa is practical. In addition, it is necessary to set the atmospheric pressure so that the semiconductor film to be formed can be formed uniformly. This value is about 0.01 Pa, although it depends on various materials and various conditions such as the pumping speed. On the other hand, the atmospheric pressure for forming the collector and emitter (corresponding to the first first conductivity type single crystal layer and the second first conductivity type single crystal layer) is epitaxial in a reduced pressure state of 100 Pa or more and atmospheric pressure or less. However, about 500 Pa to 4000 Pa is practical.

Next, more specific examples of the method for manufacturing a semiconductor multilayer film according to the present invention will be described in detail with reference to the accompanying drawings.
<Example 1>
FIG. 1 is a growth sequence showing a first embodiment of a semiconductor manufacturing apparatus and a semiconductor multilayer film manufacturing method according to the present invention. The horizontal axis indicates the processing time, and the vertical axis indicates the substrate temperature, the atmospheric pressure, and the flow rates of various gases. The upper alphabet indicates each process. This example shows changes in the substrate temperature, growth pressure, and gas flow rate when forming a multilayer film composed of an n-type doped single crystal silicon / germanium layer and a p-type doped single crystal silicon / germanium layer. Shown for each step.

  FIG. 2 shows a configuration diagram of a semiconductor manufacturing apparatus necessary for realizing the present embodiment. In order to form a multilayer film by doping with different conductivity types, in general, if one conductivity type is doped and then the other conductivity type is doped in the same growth chamber, it remains. Incorporation of the dopant deteriorates the controllability of the doping concentration. Further, since the remaining dopant inhibits gas adsorption on the crystal growth surface, the growth does not proceed uniformly, and the crystallinity of the epitaxial layer is deteriorated. Therefore, when forming semiconductor multilayer structures of different conductivity types, it is necessary to provide growth chambers corresponding to the respective conductivity types. For example, when forming an n-type doped semiconductor layer in the growth chamber 1, it is necessary to grow in a growth chamber 2 provided separately from the growth chamber 1 when forming a p-type doped semiconductor layer. From such a viewpoint, in the example of FIG. 2, the growth chamber 1 (10) and the growth chamber 2 (11) are prepared, and these are connected by the transfer chamber 12. Exhaust systems such as turbo molecular pumps 14 and 16 and dry pumps 15 and 17 are connected to each growth chamber. In FIG. 2, reference numerals 1 and 5 are valves, 2 and 6 are switching valves, 3 and 7 are conductance valves, 4 and 8 are bypass lines, and 13 is a load lock chamber.

<Preparation steps for epitaxial growth>
First, the substrate is cleaned to remove contaminants and natural oxide films on the substrate surface in advance. For example, by washing a substrate with a heated mixture of ammonia, hydrogen peroxide, and water, particles adhering to the surface of the substrate can be removed in addition to contamination by heavy metals and organic substances on the surface. Next, the oxide film formed on the substrate surface during the cleaning with the mixed solution of ammonia, hydrogen peroxide, and water is removed with a hydrofluoric acid aqueous solution, and immediately after that, the silicon substrate surface is cleaned with hydrogen atoms. It will be covered. In this state, since silicon atoms present on the outermost surface of the substrate are bonded to hydrogen, it is difficult to form a natural oxide film on the surface between the substrate cleaning and the start of growth. In addition to the hydrogen termination treatment of the substrate surface by this cleaning, in order to prevent the formation of a natural oxide film on the surface, the substrate surface is again oxidized or contaminated after the substrate is cleaned. In order to prevent this, it is preferable to transport the silicon substrate in clean nitrogen. The same applies to each of the following embodiments with respect to the substrate cleaning and transfer method performed before epitaxial growth.

Next, the cleaned substrate is placed in the load lock chamber 13 and evacuation of the load lock chamber is started. After the evacuation of the load lock chamber 13 is completed, the silicon substrate is transferred to the growth chamber 1 (10) via the transfer chamber 12. In order to prevent contaminants from adhering to the substrate surface, the transfer chamber and the growth chamber 1 are desirably in a high vacuum state or an ultrahigh vacuum state. For example, the pressure is preferably about 1 × 10 ⁻⁵ Pa or less. is there. The same applies to the growth chamber 2 (11) described later with respect to the degree of vacuum. In addition, in order to prevent the occurrence of crystal defects due to the incorporation of oxygen and carbon into the single crystal layer formed in these growth chambers, the transfer chamber, the growth chamber 1 and the growth chamber 2 are contaminated with oxygen, moisture, or organic matter. It is necessary to prevent gas containing substances from entering. For this reason, it is desirable that the transfer of the silicon substrate is started after the pressure in the load lock chamber 13 becomes about 1 × 10 ⁻⁵ Pa or less. Even if the silicon substrate surface is hydrogen-terminated, it is not possible to completely prevent the formation of an oxide film on the surface and the attachment of contaminants during transportation. Therefore, the silicon substrate surface is cleaned before epitaxial growth. As a cleaning method, for example, the natural oxide film on the surface of the substrate can be removed by the following reaction by heating the silicon substrate in a vacuum.
Si + SiO ₂ → 2SiO ↑
Alternatively, the substrate surface can also be cleaned by heating the silicon substrate with clean hydrogen supplied into the growth chamber 1 (10). In the cleaning by heating in a vacuum described above, when the substrate temperature is about 500 ° C. or higher, hydrogen that has terminated the substrate surface is desorbed, and the silicon atoms exposed on the substrate surface are exposed to the atmosphere in the growth chamber. The contained moisture and oxygen react to reoxidize the substrate surface. Then, this oxide film is reduced again, so that the unevenness of the substrate surface increases with cleaning, and the uniformity and crystallinity of the subsequent epitaxial growth are deteriorated. At the same time, since the carbon dioxide gas or organic gas contained in the atmosphere in the growth chamber adheres to the surface, the crystallinity of the epitaxial growth layer is also deteriorated due to carbon contamination. On the other hand, when a silicon substrate is heated with hydrogen supplied to the substrate surface, clean hydrogen gas is always supplied even if hydrogen desorbs from the substrate surface at a temperature of 500 ° C. or higher. Silicon and hydrogen repeatedly bond and desorb. As a result, the surface silicon is less likely to be reoxidized, and surface irregularities are not generated during cleaning, and a clean surface state can be obtained.

  In order to perform cleaning in a hydrogen atmosphere, first, hydrogen gas is supplied to the growth chamber 1 (10) (step a in FIG. 1). At this time, in order to prevent hydrogen from desorbing from the substrate surface before supplying the hydrogen gas, it is preferable that the substrate temperature be lower than 500 ° C. from which hydrogen is desorbed. Further, the flow rate of hydrogen gas is preferably 10 ml / min or more so that the gas can be supplied with good controllability, and 100 l / min or less is preferable in order to safely process the exhausted gas. At this time, the lower limit of the partial pressure of hydrogen gas in the growth chamber 1 is 100 Pa so that the gas is uniformly supplied to the substrate surface, and the upper limit may be atmospheric pressure in order to maintain the safety of the apparatus. After the hydrogen gas is supplied, the silicon substrate is heated to the cleaning temperature (step b in FIG. 1). As a heating method at this time, any mechanism or structure may be used as long as there is no contamination of the silicon substrate during heating or an extreme temperature difference in the substrate. For example, induction heating that heats a work coil by applying a high frequency, heating by a resistance heater, etc. can be applied. In addition, as a method that enables temperature control in a short time, a heating method using radiation from a lamp is used. Can do. This heating method is not limited to cleaning, and the same applies to heating during the growth of a single crystal described later.

  After heating the silicon substrate to the cleaning temperature and then heating the substrate for a predetermined time, the natural oxide film and contaminants on the surface can be removed. For example, the cleaning temperature should be 600 ° C. or more as a temperature at which the cleaning effect can be obtained. It is preferable that the temperature is 1000 ° C. or less at which the diffusion of the dopant in the substrate by the heat treatment becomes significant (step c in FIG. 1). Furthermore, the cleaning temperature needs to be as low as possible in order to reduce the influence on the structure formed before epitaxial growth. Further, the removal efficiency of the natural oxide film and contaminants on the substrate surface varies depending on the cleaning temperature, and the higher the temperature, the shorter the effect. Therefore, it is desirable to perform heating under conditions that do not perform heat treatment more than necessary. When the cleaning temperature is 700 ° C., the cleaning effect is small, and therefore the cleaning time needs to be 30 minutes. When the cleaning time is 900 ° C., the cleaning time may be 2 minutes or more. As an influence on the structure already formed, for example, considering the characteristic variation due to the diffusion of the dopant in the substrate, it is desirable to set the cleaning temperature to about 800 ° C. or less in order to suppress the diffusion of the dopant. The cleaning time may be 10 minutes.

  Further, as a method for enabling the cleaning temperature to be lowered, cleaning using atomic hydrogen can be performed. In this method, by irradiating the surface of the substrate with active hydrogen atoms, it is possible to cause an oxygen reduction reaction without raising the substrate temperature, and a cleaning effect can be obtained even at room temperature. As atomic hydrogen generation methods, hydrogen molecules are thermally dissociated by irradiating hydrogen gas to a filament such as tungsten heated to a high temperature, or hydrogen molecules are electrically generated by generating plasma in hydrogen gas. Can be dissociated, and atomic hydrogen can be generated by irradiation with ultraviolet rays. However, in this case, it is necessary to pay sufficient attention to the occurrence of metal contamination from the periphery of the electrode that generates the filament and plasma, and the generation of contaminants from quartz parts due to the plasma. In each method, it is very difficult to generate a large amount of hydrogen atoms, so it is possible to lower the temperature by dissociating a certain proportion of molecules into an atomic state in the hydrogen gas and irradiating the substrate surface. Become. For example, in order to make the cleaning time within 10 minutes, the cleaning temperature may be 650 ° C.

  While the cleaning using hydrogen has been described above, the cleaning method is the same for the other embodiments.

<Epitaxial growth>
After the cleaning is completed, the substrate temperature is lowered to a temperature at which epitaxial growth is performed, and a time for stabilizing the substrate temperature at a temperature at which epitaxial growth is performed is provided (step d in FIG. 1). In the temperature stabilization step, it is desirable to continue supplying hydrogen gas to keep the cleaned silicon substrate surface clean. However, since hydrogen gas has the effect of cooling the substrate surface, If the conditions are the same, the substrate surface temperature changes according to the gas flow rate. Therefore, even if the temperature is stable in a state where hydrogen gas having a flow rate significantly different from the total flow rate of the gas used for epitaxial growth is supplied, the substrate temperature greatly fluctuates due to the change in the gas flow rate when epitaxial growth is started. . In order to prevent this phenomenon, in the step of stabilizing the substrate temperature, it is desirable to use the hydrogen flow rate that is substantially the same as the total flow rate of the gas used for epitaxial growth. Further, it is not always necessary to provide a step of stabilizing the temperature after the substrate temperature falls to the epitaxial growth temperature. The flow rate of hydrogen gas is adjusted while lowering the substrate temperature, and when the substrate temperature reaches the epitaxial growth temperature, It is preferable that the flow rate be equal to the flow rate of the growth gas. In this case, since the epitaxial growth can be started at the same time as the substrate temperature is lowered, the throughput can be greatly improved.

<< Growth of First First Conductive Type Crystal Layer >>
Next, the epitaxial growth of the low concentration collector layer is started by supplying the source gas for the epitaxial layer and the n-type doping gas (steps e and f in FIG. 1). In the example shown in the figure, SiH ₄ and GeH ₄ are exemplified as source gases, and PH ₃ is exemplified as a doping gas. As the source gas used here, a compound composed of a group 4 element such as silicon or germanium and hydrogen, chlorine, fluorine, or the like can be used. Examples include monosilane (SiH ₄ ), disilane (Si ₂ H ₆ ), monogermane (GeH ₄ ), dichlorosilane (SiH ₂ Cl ₂ ), silicon trichloride (SiHCl ₃ ), and silicon tetrachloride (SiCl ₄ ). However, the usage is the same for other gases. In this embodiment, a method of forming a multilayer film made of single crystal silicon / germanium will be described as an example. However, a multilayer film made of single crystal silicon / germanium / carbon into which a group 4 element carbon is introduced is formed. In this case, monomethylsilane (CH ₃ SiH ₃ ), dimethylsilane ((CH ₃ ) ₂ SiH ₂ ), trimethylsilane ((CH ₃ ) ₃ SiH), or the like may be added as a carbon source gas. In addition, as the n-type doping gas, a compound composed of a Group 5 element and hydrogen, chlorine, fluorine, or the like can be used, and examples thereof include phosphine (PH ₃ ) and arsine (AsH ₃ ).

  In order to improve the breakdown voltage of the bipolar transistor, it is necessary to increase the thickness of the low concentration collector layer to about 100 nm or more. Therefore, it is desirable to increase the epitaxial growth rate to improve the throughput. For this reason, a source gas such as dichlorosilane or monosilane, which hardly causes a reaction in the gas phase even when the growth temperature and the growth pressure are increased, is used, and the temperature range is 600 ° C. or more at which the source gas begins to thermally decompose, and the upper limit. Is preferably 800 ° C. or lower so that good surface morphology is maintained. In this temperature range, the growth pressure is preferably 100 Pa or higher, which is determined by the reaction at the surface, and the upper limit is preferably atmospheric pressure or lower in order to ensure the safety of the epitaxial growth apparatus. It is possible to control the growth pressure by exhausting from the growth chamber 1 (10) illustrated in FIG. 2 through the bypass line 4 by the dry pump 1 and adjusting the opening of the conductance valve 3.

In order to finish the formation of the n-type layer in the growth chamber 1, the supply of the growth gas and the doping gas is stopped, the gas is exhausted from the reaction chamber 1, and the substrate temperature is lowered at the same time (step g in FIG. 1). When moving between the growth chambers (step h in FIG. 1), it is possible to transfer the wafer directly between the growth chambers, but the throughput between the two growth chambers performing n-type and p-type doping is also possible. In order to perform epitaxial growth well, a substrate transfer chamber 12 may be provided (FIG. 2). Hydrogen atoms that terminate the substrate surface can exist on the surface in a stable state if the substrate temperature is low. Therefore, if the contamination surface does not adhere to the substrate surface, the supply time of hydrogen is interrupted. It may be provided. For example, when the degree of vacuum in the growth chamber or the transfer chamber is 1 × 10 ⁻⁷ Pa or less, if the substrate temperature is lowered to room temperature, contaminants do not adhere to the substrate surface even if the interruption time is provided for about 10 minutes.
In addition, clean hydrogen gas can be supplied in order to prevent contaminants from adhering to the substrate surface, similar to the end of the cleaning of the substrate surface. When the substrate is moved from the growth chamber 1 (10) to the growth chamber 2 (11) via the transfer chamber 12, as in the growth chamber 1, in order to prevent contaminants from adhering to the silicon substrate surface, It is preferable to supply hydrogen gas to the growth chamber 2 so that the substrate is always in clean hydrogen gas. However, when the substrate is transferred from the growth chamber 1 to the transfer chamber, if the pressures of the growth chamber 1 and the transfer chamber are greatly different, the hydrogen pressure increases from the higher pressure to the lower pressure when the gate valve 1 is opened. Since the gas flows rapidly, there is a possibility that the substrate support position is shifted or particles are rolled up. Therefore, when the substrate is transferred, it is necessary to control the pressures of the growth chamber 1 and the transfer chamber to be substantially equal. Similarly, hydrogen gas is supplied to the growth chamber 2 in a state controlled to be the same as the pressure in the transfer chamber, and the substrate is transferred from the transfer chamber to the growth chamber 2. In addition, here, as with the cleaning of the substrate surface, by supplying hydrogen gas containing atomic hydrogen, the substrate surface easily binds to highly reactive hydrogen atoms, so that it is particularly in a low temperature state. This improves the hydrogen coverage on the substrate surface. As a result, the substrate surface is hardly contaminated while the growth is interrupted and the substrate is transported / held, so that the crystallinity of the multilayer film can be improved. The same applies to the following examples with respect to the method for supplying hydrogen gas during transport of the substrate to which atomic hydrogen is added.

<< Growth of second conductivity type single crystal layer >>
After the substrate is placed in the growth chamber 2 (11), the substrate temperature is raised to the epitaxial growth temperature while supplying clean hydrogen (step i in FIG. 1). The hydrogen gas supply conditions at this time are suitable if the substrate surface is terminated with hydrogen and is not reoxidized in the atmosphere in the growth chamber 2. In order to stabilize the substrate temperature before and after the start of epitaxial growth, the flow rate may be approximately equal to the gas flow rate during epitaxial growth described later. Since the substrate is transported to the growth chamber 2 while keeping the surface of the low-concentration n-type single crystal silicon / germanium layer grown in the growth chamber 1 clean, the p-type single crystal silicon / germanium is grown in the growth chamber 2. There is no need to clean the substrate surface before growing the layer. As a result, since a treatment at a temperature higher than the epitaxial growth temperature is not required, the diffusion of dopant in the n-type single crystal silicon / germanium layer formed in the growth chamber 1 and the silicon substrate, as well as the crystallinity due to the generation of dislocations and defects. No deterioration will occur. After the substrate temperature reaches the epitaxial growth temperature in the growth chamber 2, the growth of the p-type single crystal silicon / germanium layer as the second semiconductor layer is started by introducing the growth gas and the p-type doping gas ( FIG. 1, step j). In the figure, SiH ₄ and GeH ₄ are exemplified as source gases, and B ₂ H ₆ is exemplified as a doping gas. As the p-type doping gas, a compound composed of a Group 3 element and hydrogen, chlorine, fluorine, or the like can be used, and examples thereof include diborane (B ₂ H ₆ ). The source gas of silicon and germanium is the same as that of the low-concentration collector layer, but in order to perform epitaxial growth around the intrinsic base whose profile changes particularly at 10 nm or less, the film thickness, composition ratio, and high-precision control of the dopant are performed. Is required. Therefore, it is preferable to use disilane and germane, which can be decomposed and reacted at low temperatures to grow p-type silicon / germanium having good crystallinity.

The temperature range for epitaxial growth is 500 ° C. or higher at which disilane reacts on the substrate surface, and the upper limit is a range of 800 ° C. or lower with good surface morphology. In this temperature range, the growth pressure may be 0.01 Pa or higher, where the growth rate is determined by the reaction on the surface, and the upper limit may be 1 Pa or lower, where the reaction in the gas phase begins to occur. The same applies to the epitaxial growth conditions of p-type single crystal silicon / germanium in the following examples. The doping concentration can be controlled by the flow rate of the doping gas. For example, in order to perform p-type doping of 1 × 10 ¹⁹ cm ⁻³ , the flow rate of diborane may be 0.01 ml / min.
Similarly to the end of the low-concentration collector layer, the growth of the p-type single crystal silicon / germanium layer is completed, the supply of the growth gas and the doping gas is stopped, the gas is exhausted from the reaction chamber 2 and the substrate temperature is lowered at the same time. (FIG. 1, step k). Then, the substrate is transferred again to the growth chamber 1 in order to form an n-type single crystal layer serving as an emitter (step l in FIG. 1). The substrate transport method is the same as described above.

<< Growth of second first conductivity type single crystal layer >>
Next, an n-type single crystal silicon layer serving as an emitter is epitaxially grown on the p-type single crystal silicon / germanium layer. The epitaxial growth conditions are the same as those for the low-concentration n-type collector. However, since it is necessary to perform doping as high as possible in order to reduce the emitter resistance, disilane that can realize high-concentration doping at a low temperature is used as the source gas. (Step n in FIG. 1).

As exemplified in the present embodiment, the first first conductivity type single crystal layer, the second conductivity type single crystal layer, and the second first conductivity type single crystal corresponding to the low concentration collector, the intrinsic base, and the emitter. Since each layer is formed by epitaxial growth, crystallinity at the collector / base and base / emitter interfaces can be improved. Thus, leakage current of the transistor can be suppressed and breakdown voltage can be improved. In addition, since heat treatment at an epitaxial growth temperature or higher is not required before forming the emitter, it becomes possible to prevent impurity diffusion and mixing at the interface. As a result, a thin intrinsic base layer with a high concentration as shown in FIG. 5 can be formed, which is effective in increasing the speed and performance of the bipolar transistor. For example, when the base doping concentration is 1 × 10 ²⁰ cm ⁻³ , the bipolar transistor formed using this embodiment has a thickness of about 10 nm or less while maintaining the base doping concentration of 1 × 10 ²⁰ cm ⁻³ . Base width can be realized. Therefore, this transistor can realize a cut-off frequency exceeding 200 GHz. Further, since the high doping concentration of the base layer can be maintained, the base resistance can be reduced, the maximum oscillation frequency of the bipolar transistor can be remarkably improved, and the noise of the transistor can be reduced. In addition, the intrinsic base (p-SiGe) can control the germanium composition ratio, doping concentration, and film thickness with high precision, and the collector and emitter can improve the throughput. Cost reduction can be realized.
FIG. 8 is a cross-sectional view showing the laminated structure of the semiconductor layers in the main part of the bipolar transistor. FIG. 5 shows the depth direction distribution of the germanium composition ratio and impurity concentration in the intrinsic part of the bipolar transistor in this example. The display is the same as in FIG. In the example shown in FIGS. 5 and 8, a semiconductor layer which is usually used is inserted in a part other than the main part of the present invention in order to provide a more practical bipolar transistor. As described above, the Si substrate 30 is provided with the high-concentration n-type buried region 31 serving as the collector region. Further, an n-Si layer 35 is inserted in the upper part in this example. This layer is a layer for continuously changing the band gap with the low-concentration SiGe layer formed thereon. Each of these semiconductor layers is sufficient according to customary methods. Also, high and low concentrations of impurities are sufficient if they are commonly used in the field. Reference numerals 32, 33, and 34 other than these denote a first first-conductivity-type single-crystal layer, a second-conductivity-type single-crystal layer, and a second-first first corresponding to the low-concentration collector, intrinsic base, and emitter. It corresponds to each layer of the conductive single crystal layer.

<Example 2>
FIG. 3 is a growth sequence showing a second embodiment of the semiconductor manufacturing apparatus and semiconductor multilayer film manufacturing method according to the present invention. FIG. 3 shows changes in substrate temperature, growth pressure, and gas flow rate when forming a multilayer film composed of an n-type doped single crystal silicon / germanium layer and a p-type doped single crystal silicon / germanium layer. Shown for each step. FIG. 4 shows a configuration diagram of a semiconductor manufacturing apparatus necessary for realizing the present embodiment. In the figure, reference numeral 20 is a growth chamber, 21 is a transfer chamber, 22 is a load lock chamber, 23 is a turbo molecular pump, and 24 is a dry pump. Others are the same as FIG. The difference from Embodiment 1 is that the p-type single crystal silicon / germanium layer and the n-type single crystal silicon / germanium layer are formed in the same growth chamber. When doping with different conductivity types is continuously performed in the same growth chamber, the remaining dopant is taken in, so that the controllability of the doping concentration is deteriorated. Further, since the remaining dopant inhibits gas adsorption on the crystal growth surface, the growth does not proceed uniformly, and the crystallinity of the epitaxial layer is deteriorated. Therefore, when growth is performed by changing the conductivity type, the substrate is once taken out of the growth chamber, and the substrate is returned again after cleaning the growth chamber. At this time, the substrate is transported in an ultra-high vacuum or in a clean hydrogen atmosphere so that an oxide film is not formed on the surface of the substrate and contaminants are not attached. Is the same as in the first embodiment.

After the low concentration n-type single crystal silicon / germanium layer is formed (steps e and f in FIG. 3), the substrate is transferred to the transfer chamber and the growth chamber is cleaned (step h in FIG. 3). In addition to heating the growth chamber in a vacuum, the growth chamber can also be heated in a state where hydrogen gas or a halogen-based gas such as Cl ₂ or HCl is allowed to flow. As a heating method, a dedicated heating mechanism provided for heating the growth chamber may be used, or the growth chamber may be heated using a mechanism for heating the substrate. For example, when hydrogen gas is used, the flow rate of hydrogen gas is 10 ml / min or more so that the gas is uniformly supplied, and 100 l / min or less may be used for processing the exhausted hydrogen gas. In addition, it is preferable that the hydrogen partial pressure is 10 Pa or more so that hydrogen is uniformly supplied, and the atmospheric pressure is less than atmospheric pressure in order to ensure the safety of the epitaxial growth apparatus. The temperature in the growth chamber where cleaning is performed differs depending on the material used and the location of the shape, as well as the arrangement of the heating mechanism, but it is effective for cleaning at low temperatures because the dopant is difficult to deposit in the cooled part during epitaxial growth. Can be obtained. For example, in stainless steel or the like cooled by cooling water or other cooling medium, the dopant is difficult to deposit on the surface during epitaxial growth, so heating may be performed at 50 ° C. or higher at which the cleaning effect starts to be obtained. The temperature may be set to 250 ° C. or lower, which may cause the leakage of the vacuum vessel due to the expansion of stainless steel. On the other hand, in a portion that cannot be cooled during epitaxial growth, a high-concentration dopant may be deposited together with silicon or germanium during epitaxial growth, and therefore cleaning at a relatively high temperature is required. For example, a quartz susceptor or the like that supports the substrate may be at 200 ° C. or higher at which a cleaning effect can be obtained. Since the effect of cleaning greatly depends on the temperature and the like, the time required for heating for cleaning varies depending on the temperature, but it is desirable to perform processing at a temperature as high as possible in order to prevent a decrease in throughput. For example, when the temperature of the high temperature part is about 1000 ° C., the heating time may be about 10 minutes.

On the other hand, when HCl is used as the cleaning gas, the cleaning effect can be obtained at a lower temperature than hydrogen gas. For example, when the flow rate of HCl is 50 ml / min and the pressure is 100 Pa, cleaning is completed in about 10 minutes by maintaining the surface temperature at about 500 ° C. with a quartz susceptor or the like. Further, when ClF ₃ is used as a cleaning gas, silicon etching reaction occurs even at room temperature. Therefore, by setting the pressure of ClF ₃ to 10 Pa or more, silicon and dopant deposited in the growth chamber can be cleaned. However, since halogen-based gases such as ClF ₃ may cause corrosion of metal parts and the like, it is necessary to manage the moisture concentration and to periodically replace the exhaust pipes.

According to the present embodiment, the dopant remaining in the growth chamber after doping can be removed, so that the dopant concentration in the single crystal silicon / germanium layer grown without flowing a doping gas can be reduced.
After the cleaning is completed, the substrate is placed again in the growth chamber to form a p-type single crystal silicon / germanium layer (step j in FIG. 3). The same applies before the growth of the n-type single crystal silicon to be the emitter (steps l to n in FIG. 3).

  According to this embodiment, even if there is only one growth chamber, it is possible to remove the dopant remaining in the growth chamber after doping. Therefore, in addition to the effects of the first embodiment, different dopants can be added. It is possible to significantly reduce the cost of the epitaxial growth apparatus for forming the used multilayer film.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various design changes can be made without departing from the spirit of the present invention. For example, in the embodiments, the case of a multilayer film composed of an n-type single crystal silicon / germanium layer, a p-type single crystal silicon / germanium layer, and an n-type single crystal silicon layer has been described, but the single crystal silicon / germanium / carbon layer, etc. It goes without saying that can be used.

  When manufacturing a semiconductor multilayer film composed of a plurality of single crystal layers having different conductivity types, the present invention suppresses blurring of impurity distribution in each layer, and there is no impurity at the interface of each layer, so that crystal defects are generated in the multilayer film. High concentration doping is possible by increasing the growth pressure. In addition, it is possible to provide a method for forming a semiconductor multilayer film that can improve throughput. Further, as is clear from the above-described embodiments, the method for manufacturing a semiconductor multilayer film according to the present invention is very useful when applied to a method for manufacturing a bipolar transistor. That is, according to the semiconductor multilayer film manufacturing method of the present invention, the crystallinity at the collector / base and base / emitter interfaces can be improved, so that the leakage current of the bipolar transistor can be suppressed and the breakdown voltage can be improved. Further, since the germanium composition ratio, impurity concentration, and film thickness in the intrinsic base of the bipolar transistor can be controlled with high accuracy and good reproducibility, a very thin junction can be obtained at a high concentration. Thus, by applying the method for manufacturing a semiconductor multilayer film of the present invention to a method for manufacturing a bipolar transistor, it is possible to operate the transistor at high speed and reduce noise. Furthermore, cost reduction can be realized by improving throughput in collector and emitter growth.

FIG. 1 is a process sequence showing a method for producing a semiconductor multilayer film according to the present invention. It is a block diagram of the epitaxial growth apparatus for implement | achieving the process sequence shown in FIG. FIG. 3 is a process sequence showing a second embodiment of the method for producing a semiconductor multilayer film according to the present invention. It is a block diagram of the epitaxial growth apparatus for implement | achieving the process sequence shown in FIG. FIG. 5 is a characteristic diagram showing the distribution in the depth direction of the impurity concentration and the germanium composition ratio in the semiconductor multilayer film according to the present invention. FIG. 7 is a characteristic diagram showing the distribution in the depth direction of the impurity concentration and germanium composition ratio in the conventional semiconductor multilayer film. FIG. 7 is a cross-sectional view of the semiconductor multilayer film of the present invention. FIG. 8 is a cross-sectional view of the semiconductor multilayer film illustrated in the first embodiment.

Explanation of symbols

1, 5: valve, 2, 6: switching valve, 3, 7: conductance valve, 4, 8: bypass line, 10: growth chamber, 11: growth chamber, 12: transfer chamber, 13: load lock chamber, 14: Turbo molecular pump, 15: dry pump, 16: turbo molecular pump, 17: dry pump, 20: dry pump, 21: transfer chamber, 22: load lock chamber, 23: turbo molecular pump, 24: dry pump, 30: semiconductor Substrate 31: High concentration impurity buried region 32: First first conductivity type single crystal layer 33: Second conductivity type single crystal layer 34: Second first conductivity type single crystal layer 35: Inserted Semiconductor layer.

Claims (4)

  On the first conductivity type region provided on the surface of the single crystal substrate, the first first conductivity type single crystal layer and the first conductivity type opposite to the first conductivity type provided on the first first conductivity type single crystal layer A method for forming a semiconductor multilayer film comprising a second conductivity type single crystal layer of conductivity type and a second first conductivity type single crystal layer provided on the second conductivity type single crystal layer, wherein the semiconductor During the formation of the multilayer film, the single crystal substrate is always held in a hydrogen atmosphere or in a vacuum, and the pressure for growing the second conductivity type single crystal layer is adjusted to the first first conductivity type single crystal layer and the second conductivity type. A method for producing a semiconductor multilayer film, wherein the pressure is lower than a pressure for growing a first conductivity type single crystal layer.   The first first conductivity type single crystal layer and the second first conductivity type single crystal layer are formed in a first growth chamber, and the second conductivity type single crystal layer is formed in a second growth chamber. Forming and growing a pressure of the second conductivity type single crystal layer lower than a pressure of growing the first first conductivity type single crystal layer and the second first conductivity type single crystal layer. The method for producing a semiconductor multilayer film according to claim 1.   The first conductivity type single crystal layer, the second conductivity type single crystal layer, and the second first conductivity type single crystal layer are formed in the same growth chamber, and the second conductivity type single crystal layer is formed. 2. The semiconductor multilayer film according to claim 1, wherein a pressure for growing the first conductive type single crystal layer and a pressure for growing the second first conductive type single crystal layer is lower. Manufacturing method.   Any one of the group consisting of the first first conductivity type single crystal layer, the second conductivity type single crystal layer, and the second first conductivity type single crystal layer has silicon or germanium as a main component. The method for producing a semiconductor multilayer film according to claim 1, further comprising:

Images