5. BEST MODE OF CARRYING OUT THE INVENTION

[0024] An embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a block diagram showing the arrangement of an MOCVD system according to an embodiment of the present invention.

[0025] In FIG. 1 , reference numeral 1 denotes a source tank which holds a lead dibivaloylmethane complex Pb(DPM) ₂ ; 2 , a source tank which holds an organometallic compound source containing Ti, e.g., Ti(OiPr) ₄ ; 3 , a source tank which holds an organometallic compound source containing Zr, e.g., Zr(OtBt) ₄ ; 4 to 7 , mass-flow controllers for respectively controlling the flow rates of Pb(DPM) ₂ gas, Ti(OiPr) ₄ gas, Zr(OtBt) ₄ gas, and NO ₂ gas; 8 , a reaction chamber; 9 , a shower head serving as a gas supply means; and 10 , a semiconductor substrate.

[0026] In this embodiment, the shower head 9 is used as a means for supplying an organic metal gas and oxidizing gas to the substrate 10 at uniform density. FIG. 2 is a bottom view of the shower head 9 , and FIG. 3 is a sectional view of the shower head 9 .

[0027] The lower structure of the shower head 9 is constructed by AlN ceramic plates 11 and 12 with good thermal conductivity. The ceramic plates 11 and 12 have a plurality of first ejection holes 13 for ejecting an organic metal gas and a plurality of second ejection holes 14 for ejecting an oxidizing gas (NO ₂ gas). A heater 15 having a shape shown in FIG. 4 is printed on the upper surface of the AlN ceramic plate 11 , which is formed to detour the ejection holes 13 and 14 . The ceramic plates 11 and 12 accordingly sandwich the heater 15 therebetween. The heater 15 generates heat by making a current flow therein, so that the ceramic plates 11 and 12 are heated to a temperature (e.g., 240° C. when a PZT film is to be formed as in this embodiment) higher than the thermal decomposition point of the organic metal gas but lower than the film forming temperature.

[0028] In contrast, an upper structure 16 of the shower head 9 is made of Al. The upper structure 16 is heated by a heater (not shown) to a temperature (e.g., 200° C. when the PZT film is to be formed) higher than a temperature at which the organic metal gas can keep the vapor state but lower than the thermal decomposition point of the organic metal gas. When a buffer plate (not shown) made of Al ₂ O ₃ or the like which has thermal conductivity lower than that of AlN is then formed between the AlN ceramic plate 12 and upper structure 16 , the AlN ceramic plates 11 and 12 can be kept at a temperature higher than that of the upper structure 16 .

[0029] A thin film forming method using the above-described MOCVD system will be described next. First, the source tank 1 is heated to evaporate the lead dibivaloylmethane complex Pb(DPM) ₂ , and the source tank 2 is simultaneously heated to evaporate an organometallic compound source Ti(OiPr) ₄ . The resultant Pb(DPM) ₂ gas and Ti(OiPr) ₄ gas and NO ₂ gas are introduced into the evacuated reaction chamber 8 . At this time, the pressure of the reaction chamber 8 is 0.005 torr, the flow rate of Pb(DPM) ₂ gas is 0.2 sccm, the flow rate of Ti(OiPr) ₄ gas is 0.14 sccm, the flow rate of NO ₂ gas is 2.3 sccm, and a film forming temperature (substrate temperature) is 445° C. Under these conditions, Pb(DPM) ₂ gas and Ti(OiPr) ₄ gas pass through a path shown in FIG. 3 and are ejected from the ejection holds 13 , and NO ₂ gas passes through a path shown in FIG. 3 and is ejected from the ejection holes 14 . With this processing, a crystal nucleus with a perovskite structure made of PbTiO ₃ is formed on the substrate 10 .

[0030] Successively, the source tank 3 is heated to evaporate Zr(OtBt) ₄ , and the resultant Zr(OtBt) ₄ gas is introduced into the reaction chamber 8 together with the gases described above. The flow rate of Zr(OtBt) ₄ gas is 0.175 sccm, and other conditions are the same as in the above description. Zr(OtBt) ₄ gas is ejected from the ejection holes 13 together with Pb(DPM) ₂ gas and Ti(OiPr) ₄ gas. With this processing, a PZT. film (PbZrxTil-xO ₃ film) with the perovskite structure is formed on the substrate 10 .

[0031] In this embodiment, the organic metal gas and oxidizing gas can be supplied to the surface of the substrate 10 at uniform density by using the shower head 9 . The gas pipes to the shower head 9 are kept at a temperature (160 to 200° C. when the PZT film is to be formed) lower than thermally decomposition point of the organic metal gas, and the vicinity of the ejection holes 13 of the shower head 9 is heated to a temperature higher than the thermal decomposition point of the organic metal gas. With this processing, the organic metal gas which is easily thermally decomposed can be transported to the vicinity of the ejection holes of the shower head 9 and then thermally decomposed at the vicinities of the ejection holes 13 . Therefore, the film formation rate can be made twice or more the conventional rate, from 10 nm/min to 25 nm/min. Note that the heater 15 heats both the ejection holes 13 and 14 in this embodiment. However, if the heater 15 heats only the vicinity of the ejection holes 13 , the same effect can also be obtained.

[0032] Since the AlN has good thermal conductivity, variations in temperature of the substrate-side surface of the shower head 9 can be suppressed within ±1° C., thereby obtaining the satisfactory uniformity in temperature. Thus, the satisfactory composition and uniformity in thickness of the thin film formed on the substrate 10 can be ensured, and the film formation rate can be greatly increased as compared with that in the prior art.

[0033] Note that a nucleus forming process and a film forming process are performed at a high vacuum of 0.005 torr in this embodiment, but the film forming process may be performed at a low vacuum. That is, the lead dibivaloylmethane complex Pb(DPM) ₂ and organometallic compound source Ti(OiPr) ₄ are dissolved in an organic solvent (butyl acetate solution) and evaporated together with the organic solvent, and the resultant gas is introduced into the reaction chamber 8 at a pressure of 0.005 torr to form a nucleus. Successively, the organometallic compound source Zr(OtBt) ₄ is dissolved in the organic solvent together with the above-described Pb(DPM) ₂ and Ti(OiPr) ₄ and evaporated with the organic solvent, and the resultant gas is introduced into the reaction chamber 8 at a pressure of about 0.1 to 0.5 torr to form a film. At this time, to make the respective partial pressures equal, an inert gas is introduced so as to make a total flow rate of gases about 20 to 100 times. This can increase the internal pressure of the shower head 9 , thereby uniformity supplying the organic metal gas to the surface of the substrate.

[0034] This embodiment uses the post-mix type shower head 9 which supplies the organic metal gas and the oxidizing gas independently. However, a pre-mix type shower head for supplying the organic metal gas and oxidizing gas together may be used. In addition, the PZT film is formed on the substrate 10 in this embodiment, but the film is not obviously limited to the PZT film.

[0035] As described above, according to this embodiment, the inside of the vicinity of the substrate-side surface of the shower head 9 is heated to a temperature higher than the thermal decomposition point of the organic metal gas but lower than the film forming temperature. With this processing, the satisfactory composition and uniformity in thickness of the thin film formed on the substrate 10 can be ensured, and the film formation rate can be greatly increased as compared with that in the prior art. As a result, a thin film forming apparatus with good mass production can be realized. In addition, since the inside of the vicinity of the substrate-side surface of the shower head 9 is to be heated, the heater 15 is not exposed, thereby preventing the heater 15 from oxidiation.

[0036] 6. Industrial Applicability

[0037] As has been described above, the present invention is suitable to forming a high-quality thin film.