Abstract: A disadvantage upon heat treatment in an oxygen atmosphere of a dielectric film formed on a lower electrode of capacitance device of DRAM that oxygen permeating the lower electrode oxidizes a barrier layer to form an oxide layer of high resistance and low dielectric constant is prevented. An Ru silicide layer is formed on the surface of a plug in a through hole formed below a lower electrode for an information storage capacitance device C and an Ru silicon nitride layer is formed further on the surface of the Ru silicide layer. Upon high temperature heat treatment in an oxygen atmosphere conducted in the step of forming a dielectric film on the lower electrode, the Ru silicon nitride layer is oxidized sacrificially into an Ru silicon oxynitride to prevent progress of oxidation in the Ru silicide layer.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: A disadvantage upon heat treatment in an oxygen atmosphere of a dielectric film formed on a lower electrode of capacitance device of DRAM that oxygen permeating the lower electrode oxidizes a barrier layer to form an oxide layer of high resistance and low dielectric constant is prevented. An Ru silicide layer is formed on the surface of a plug in a through hole formed below a lower electrode for an information storage capacitance device C and an Ru silicon nitride layer is formed further on the surface of the Ru silicide layer. Upon high temperature heat treatment in an oxygen atmosphere conducted in the step of forming a dielectric film on the lower electrode, the Ru silicon nitride layer is oxidized sacrificially into an Ru silicon oxynitride to prevent progress of oxidation in the Ru silicide layer.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: A process for forming the lower and upper electrodes of a high dielectric constant capacitor in a semiconductor device from an organoruthenium compound by chemical vapor deposition. This chemical vapor deposition technique employs an organoruthenium compound, an oxidizing gas, and a gas (such as argon) which is hardly adsorbed to the ruthenium surface or a gas (such as ethylene) which is readily adsorbed to the ruthenium surface. This process efficiently forms a ruthenium film with good conformality in a semiconductor device.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: Described is a manufacturing method of an integrated circuit which uses a thin film such as platinum or BST as a hard mask upon patterning ruthenium or the like, thereby making it possible to form a device without removing the hard mask. In addition, the invention method makes it possible to interpose a protecting film such as platinum in order to prevent, upon removing a resist used for the patterning of the hard mask, an underlying ruthenium film or the like from being damaged.

Abstract: A ruthenium electrode with a low amount of oxygen contamination and high thermal stability is formed by a chemical vapor deposition method. In the chemical vapor deposition method using an organoruthenium compound as a precursor, the introduction of an oxidation gas is limited to when the precursor is supplying, and the reaction is allowed to occur at a low oxygen partial pressure. Consequently, it is possible to form a ruthenium film with a low amount of oxygen contamination. Further, after formation of the ruthenium film, annealing at not less than the formation temperature is performed, thereby forming a ruthenium film with high thermal stability.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: A disadvantage upon heat treatment in an oxygen atmosphere of a dielectric film formed on a lower electrode of capacitance device of DRAM that oxygen permeating the lower electrode oxidizes a barrier layer to form an oxide layer of high resistance and low dielectric constant is prevented. An Ru silicide layer is formed on the surface of a plug in a through hole formed below a lower electrode for an information storage capacitance device C and an Ru silicon nitride layer is formed further on the surface of the Ru silicide layer. Upon high temperature heat treatment in an oxygen atmosphere conducted in the step of forming a dielectric film on the lower electrode, the Ru silicon nitride layer is oxidized sacrificially into an Ru silicon oxynitride to prevent progress of oxidation in the Ru silicide layer.

Abstract: Described is a manufacturing method of an integrated circuit which uses a thin film such as platinum or BST as a hard mask upon patterning ruthenium or the like, thereby making it possible to form a device without removing the hard mask. In addition, the invention method makes it possible to interpose a protecting film such as platinum in order to prevent, upon removing a resist used for the patterning of the hard mask, an underlying ruthenium film or the like from being damaged.

Abstract: Plug electrodes of silicon are formed being buried in the through holes in a first insulating film, the plug electrodes being electrically connected to the source and drain regions of a MISFET on the main surface of a semiconductor substrate. Then, a second insulating film is deposited thereon and holes are formed therein such that the plug electrodes of silicon are exposed. A barrier film is formed on the surfaces of the silicon plugs, and in the holes are formed a dielectric to form lower electrodes of the capacitor elements and an upper electrode therefor.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: In a semiconductor device including a plurality of memory cells, a deposition preventing film is formed on an interlayer insulating film in which a plurality of holes are formed, or a seed film is selectively formed on the interlayer insulating film and on an inner surface and a bottom surface of the holes. A film of Ru, Ir or Pt is deposited by chemical vapor deposition on the deposition preventing film, or on the interlayer insulating film by utilizing the seed film, under the condition where underlayer dependency occurs. In consequence, lower electrodes are formed in accordance with a pattern of the deposition preventing film or the seed film. A dielectric film is formed on the lower electrodes and the deposition preventing film at a predetermined temperature. The material of the lower electrodes does not lose conduction even when exposed to the predetermined temperature employed for forming the dielectric film. Upper electrodes are further formed on the dielectric film.

Abstract: A semiconducting diamond electroluminescence element comprises an electrically conductive substrate, a semiconducting diamond layer formed on the substrate, an insulating diamond layer formed on the semiconducting diamond layer, a front electrode formed on the insulating diamond layer, and a back electrode formed on the conductive substrate in ohmic contact with the same. The color of light to be emitted by the semiconducting diamond electroluminescence element can readily be determined by changing the impurity content in the semiconducting diamond layer. The luminescence intensity of the semiconducting diamond electroluminescence element can readily be changed by changing the voltage applied across the front and back electrodes without entailing dielectric breakdown.

Abstract: Disclosed herein is a MIS type diamond field-effect transistor comprising a diamond semiconductor layer provided as an active layer by chemical vapor deposition (CVD), and a diamond insulator layer provided on the diamond semiconductor layer also by CVD, a gate electrode being formed on the diamond insulator layer, wherein a diamond insulator undercoat is provided on a non-diamond substrate by CVD, and the diamond semiconductor layer and the diamond insulator layer are sequentially provided on the diamond insulator undercoat. The MIS type diamond field-effect transistor with this structure ensures that in the manufacture thereof, a diamond insulator undercoat of large area can be formed on a non-diamond substrate of CVD, whereby a large number of elemental devices can be fabricated simultaneously.

Abstract: A schottky diode manufacturing process employing diamond film comprises forming a B-doped p-type polycrystalline diamond film on a low-resistance p-type Si substrate by CVD using a source gas consisting of CH.sub.4, H.sub.2 and B.sub.2 H.sub.6, forming an ohmic contact on the back of the p-type Si substrate, and forming a metal electrode of Al, Pt Au, Ti or W on the B-doped p-type polycrystalline diamond film. The B/C concentration ratio of the source gas is greater than 0.01 ppm and less than 20 ppm.

Abstract: A compound semiconductor device having a channel layer which is made of periodically laminated structure of thin-film layers of compound semiconductor substantially being different from each other. The difference of energy between the conduction band and the valence band of compound semiconductor thin-film layers of one side is less than that of the other side thin-film layers, moreover the electron mobility in low electric field application in the thin-film layers of compound semiconductor of one side is greater than that of the other side thin-film layers, besides the electron mobility in high electric field application in the thin-film layers of compound semiconductor of one side is less than that of the other side thin-film layers, and/or the impact ionization of valence electron generated in high electric field application takes place earlier than the thin-film layers of compound semiconductor of the other side.