Abstract: A method of manufacturing a code pattern on a semiconductor substrate with an array of substantially parallel buried bit lines integral therewith and with word lines above the buried bit lines, includes: forming a titanium nitride layer above the word lines, forming and patterning a code mask above the titanium nitride layer, implanting impurities into the substrate through openings in the code mask to form the code pattern, and performing rapid thermal annealing of the implant. The step height of the titanium nitride layer is employed to form the code identification on the substrate.

Abstract: A ROM device with an array of cells and a method of manufacturing comprises: forming closely spaced conductors in the surface of a semiconductor substrate having a second type of background impurity. Insulation is formed on the substrate. Closely spaced, parallel, conductors on the insulation are arranged orthogonally to the line regions. Glass insulation is formed over the conductors. Reflowing the glass insulation, forming contacts and forming a metal layer on the glass insulation follow. A resist is formed, exposed forming a resist metal pattern, then etching through the resist to pattern metal and removing the resist. Depositing a resist onto the patterned metal, and exposing the second resist with a custom code pattern, developing the resist into a mask follow. Impurity ions are implanted into the substrate adjacent to the conductors through the openings in a second resist layer.

Abstract: A ROM device with an array of cells has conductors formed in a substrate. Insulation is formed, and parallel conductors are formed orthogonally to the line regions, as thin as about 2000 .ANG.. Glass insulation having a thickness of about 3000 .ANG. or less, formed over the conductors is is reflowed. Contacts and a metal layer on the glass insulation are formed. Resist is patterned and used for etching the resist pattern in the metal. Removal of the second resist and device passivation with a layer having a thickness of about 1000 .ANG., precede activation of the impurity ions by annealing the device at less than or equal to about 520.degree. C. in a reducing gas atmosphere. After resist removal, a second resist is formed and exposed with a custom code pattern to form a mask. Ions are implanted into the substrate with a dosage of between about 1 E 14 and 3 E 14 atoms/cm.sup.2 with an energy of less than or equal to 200 keV adjacent to the conductors through the openings in the insulation.

Abstract: The invention describes recessed buried conductive regions formed in a trench in the substrate that provides a smooth surface topology, smaller devices and improved device performance. The buried regions have two conductive regions, the first on the trench sidewalls, the second on the trench bottom. In addition, two buried layers are formed between adjacent buried conductive regions: a threshold voltage layer near the substrate surface and an anti-punchthrough layer formed at approximately the same depth as the conductive regions on the trench bottoms. The first conductive region and the anti-punchthrough layer have the effect of increasing the punchthru voltage without increasing the threshold voltage. The first and second regions also lowers the resistivity of the buried regions allowing use of smaller line pitches and therefore smaller devices. Overall, the recessed conductive regions and the two buried layers allow the formation of smaller devices with improved performance.