Abstract: The single-poly EEPROM includes a first PMOS transistor serially connected to a second PMOS transistor. The first and second PMOS transistors are both formed on an N-well of a P type substrate. The first PMOS transistor includes a floating gate, a first P+ doped drain region and a first P+ doped source region. The second PMOS transistor includes a gate and a second P+ doped source region. The first P+ doped drain region of the first PMOS transistor serves as a drain of the second PMOS transistor. A diode is located in the P type substrate including a P-well and a N+ doped region. The floating gate overlaps with the N-well and extends to the N+ doped region. The overlapped region of the P-well and the N+ doped region junction beneath the floating gate serves as an avalanche injection point in the vicinity of the first PMOS transistor.

Abstract: A DRAM cell and a method for fabricating the same are provided. The method includes: forming a trench in a substrate; forming a first capacitor dielectric layer on the surface of the trench; forming a conducting layer inside the trench; forming a second capacitor dielectric layer on the surface of the substrate and on the conducting layer, wherein the substrate around the first and second capacitor dielectric layers serves as a bottom electrode; forming a protruding electrode on the substrate, the protruding electrode being on the substrate around the trench and covering a junction between the trench and the substrate; and electrically connecting the protruding electrode and the conducting layer, the conducting layer and the protruding electrode being an upper electrode.

Abstract: A DRAM cell and a method for fabricating the same are provided. The method includes: forming a trench in a substrate; forming a first capacitor dielectric layer on the surface of the trench; forming a conducting layer inside the trench; forming a second capacitor dielectric layer on the surface of the substrate and on the conducting layer, wherein the substrate around the first and second capacitor dielectric layers serves as a bottom electrode; forming a protruding electrode on the substrate, the protruding electrode being on the substrate around the trench and covering a junction between the trench and the substrate; and electrically connecting the protruding electrode and the conducting layer, the conducting layer and the protruding electrode being an upper electrode.

Abstract: A test key includes a substrate, a deep trench capacitor formed in the substrate, and at least one active region defined on the substrate. The active region comprises a first region, a second region and an ion well. A thermal oxide layer is formed in the first region. A top-thin oxide layer is formed in the second region. The second region overlaps with the deep trench capacitor. At least one word line partially overlapping with the top-thin oxide layer. The ion well is electrically connected with a polysilicon electrode of the deep trench capacitor. The thermal oxide layer within the first region does not overlap with any word line.

Abstract: A method of forming the lower electrode of a capacitor capable of withstanding the flushing force produced by a cleaning agent. A lower electrode having a rectangular profile when viewed from the top is provided. The lower electrode is bounded by a pair of ends and a pair of sides. The ends and the sides are linked together. The ends have a wedge shape. The sides have edges that cave in towards the center, thereby forming a recess region between the sides. A flushing operation is carried out using a cleaning solution. The cleaning solution flows from one end of the electrode to the other end along the sides.

Abstract: A method of forming the lower electrode of a capacitor capable of withstanding the flushing force produced by a cleaning agent. A lower electrode having a rectangular profile when viewed from the top is provided. The lower electrode is bounded by a pair of ends and a pair of sides. The ends and the sides are linked together. The ends have a wedge shape. The sides have edges that cave in towards the center, thereby forming a recess region between the sides. A flushing operation is carried out using a cleaning solution. The cleaning solution flows from one end of the electrode to the other end along the sides.

Abstract: The present invention provides a method of forming a DRAM contact plug. Multiple word lines are formed on the substrate to divide the active area into at least one bit line contact area and one node contact area. Multiple poly landing pads are then formed between the multiple word lines. The spacers and poly landing pads between the word lines outside the active area are removed thereafter. A dielectric layer is then formed to cover both the word lines and poly landing pads as well as to fill the spaces between the word lines outside the active area. Finally, a bit line contact plug and a node contact plug, both electrically connecting to the poly landing pads, are formed in each bit line contact plug hole and node contact plug hole, respectively.

Abstract: A process for fabricating a lower electrode of a capacitor on a substrate having a dielectric layer formed thereon. A node contact opening is first formed in the dielectric layer to expose a part of a conductive portion on the substrate. A node contact is then formed in the node contact opening such that the node contact protrudes from the dielectric layer. Subsequently, an insulating layer and a conductive layer are formed in sequence on the dielectric layer and the node contacts. The conductive layer and the insulating layer are patterned in sequence to expose a part of the node contacts and leave the residual insulating layer as a protruding part and a link layer, in which the protruding part is located on a part of the node contacts and a part of the dielectric layer, and the link layer is located on the dielectric layer outside the node contacts, serving as a link for the dielectric layer and the protruding part.

Abstract: A method of fabricating a capacitor includes formation of a stacked layer formed by alternately forming conductive layers and isolation layers and then patterning these layers to form a stacked layer. An opening is formed above the source/drain region. A conductive spacer is formed on the sidewall of the opening. The conductive spacer is used as a mask. The dielectric layer below the stacked layer exposed by the opening is removed to form a contact hole. The top isolation layer of the stacked layer is removed. A conductive layer is formed over the substrate to fill the contact hole. The conductive spacer is covered by the conductive layer to form a raised region. A stacked spacer is formed beside the raised region. The isolation spacers of the stacked spacer and the isolation layer are removed to expose a storage electrode.

Abstract: A method is disclosed for forming the lower storage node and contact for capacitors on a semiconductor wafer. The method includes an etch back process to remove a portion of the silicon oxide layer around the mouth of the contact hole to produce a rounded shoulder where the walls of the contact hole meet the face of the silicon oxide layer. When a contact plug is formed during a subsequent deposition process, the rounded shoulder results in local enlargement of the contact plug as well as filleting of reentrant corners. The contact plug therefore sustains substantially reduced mechanical stress during subsequent wafer cleaning processes. This stress reduction results in a reduced rate of lower node collapse and increased production yield of finished product.

Abstract: A method for forming a capacitor in DRAM is disclosed. The method includes: providing a conductor defined on a first dielectric layer; forming a second dielectric layer on the conductor; then forming a polysilicon layer on the second dielectric layer, the polysilicon layer serves as an etching mask; next, etching the second dielectric layer; removing said polysilicon layer; etching said conductor; and finally removing said second dielectric layer.

Abstract: A silicon oxide layer is formed on a substrate surface of a semiconductor wafer. A node contact is formed in the silicon oxide layer. A storage node is formed on the silicon oxide layer and connects to the node contact. An ion implantation process is performed as a surface process on the silicon oxide layer. A silicon nitride layer is subsequently formed on the surfaces of the silicon oxide layer and the storage node. Finally, a high-temperature oxidation process is performed. The surface process reduces the difference in the incubation time for the silicon nitride layer deposited on the silicon oxide layer and on the surface of the storage node. The surface process also relieves problems associated with the nonuniformity in thickness of the silicon nitride layer. Neck-oxidation at the interface of the storage node and the node contact is thus prevented.

Abstract: A fabrication method for a borderless buried bit line is described. A substrate wherein a plurality of word lines and source/drain regions formed thereon is provided. A first insulation material is formed over the substrate and a node landing pad is formed in the first insulation material, wherein the node landing pad is covered by a second insulation material. A bit line contact is further formed in the first insulation material, wherein the bit line contact is covered by a third insulation material. Therefore, a trench is further formed along the sides of the bit line contact, traversing across the first insulation material. A partial filling of the trench with a conductive material, followed by filling the trench with a fourth insulation layer to complete the formation of the buried bit line.

Abstract: The present invention provides a method of forming a node contact hole on a semiconductor wafer. The semiconductor wafer comprises a silicon substrate, a first dielectric layer positioned on the silicon substrate, two bit lines positioned on the first dielectric layer which form a first groove between the two bit lines and the surface of the first dielectric layer, and a second dielectric layer positioned on each of the two bit lines. A lithographic process is performed to form a photoresist layer on the second dielectric layer with at least one second groove extending down to the second dielectric layer wherein the second groove is positioned above the first groove and is perpendicular to the first groove. An etching process is performed along the second groove of the photoresist layer to remove the second dielectric layer and the first dielectric layer under the second groove down to the surface of the silicon substrate so as to approximately form the node contact hole.

Abstract: A method for forming a MOSFET is described. The feature of this invention is that an epitaxial silicon layer with device isolation structures is formed over a substrate, wherein each device isolation structure is made of oxide. The invention need not etch the substrate for forming a device isolation structure. As a result, the invention not only prevents stress and dislocation generation and avoids leakage current, but also provides an easily method for forming a device isolation structure.

Abstract: A semiconductor wafer comprises a substrate, a first conductive layer and a dielectric layer covering the first conductive layer. A thin-film layer is formed over the dielectric layer. The thin-film layer comprises a hole that penetrates down to the surface of the dielectric layer and the hole is located above the first conductive layer. A first barrier layer is formed on the surface of the semiconductor wafer to cover the thin-film layer. Next, a spacer is formed on the internal walls of the hole. Thereafter, a first dry etching process is performed to form a contact hole. A second barrier layer is then formed on the internal walls of the contact hole. A second conductive layer is formed on the surface of the semiconductor wafer that fills the contact hole. A lithographic process is performed to define a pattern and a location of the storage node in a photo resist layer above the contact hole.

Abstract: A method of forming a borderless contact is described. An ion implantation process and a thermal process are performed on a device isolation structure to form a silicon nitride layer therein. During a process of forming a borderless contact window, the silicon nitride layer can serve as an etching stop layer to protect the device isolation structure from overetching. As a result, no recess is formed, and leakage current is avoided.

Abstract: A method of fabricating a node contact hole is disclosed. The fabrication includes the steps as follows. At first, the first interpoly dielectric (IPD1) layer is formed over the semiconductor substrate. The landing pad is formed in the first interpoly dielectric layer. The polycide bit line is formed on the first interpoly dielectric layer. Afterwards, the second interpoly dielectric (IPD2) layer is formed over the first interpoly dielectric layer. Next, the defined photoresist layer is formed on the second interpoly dielectric layer, then using reflow and curing processes to form the heated photoresist layer. Afterwards, a portion of the second interpoly dielectric layer is firstly etched, using the heated photoresist layer as a mask. The depth is formed in the second interpoly dielectric layer. Then the heated photoresist layer is removed. Next, in order to the silicon nitride layer and the polysilicon layer are deposited over the second interpoly dielectric layer.

Abstract: A method of forming a capacitor for a dynamic random access memory (DRAM) cell using a selective hemispherical grain (s-HSG) structure after the removal of SiON by phosphoric acid (H3PO4) is disclosed. The method includes: Providing a semiconductor substrate having a semiconductor structure formed thereon; forming an interlayer dielectric layer over the semiconductor structure; patterning the interlayer dielectric layer; depositing an amorphous-silicon (a-Si) layer over the interlayer dielectric layer; depositing a SiON layer on the a-Si layer; patterning the SiON layer and the a-Si layer layer; removing the SiON layer by H3PO4 wet etching; forming a s-HSG silicon layer over the patterned a-Si layer; depositing a conformal interpoly dielectric layer along a surface of the resulting structure; and finally forming a polysilicon layer over the interpoly dielectric layer.

Abstract: A method of fabricating a narrow bit line structure is disclosed. The fabrication includes the steps as follows. At first, the interpoly dielectric layer is formed over the MOSFET. Then the landing pad is formed in the interpoly dielectric layer. Afterwards, the first polysilicon layer, the tungsten silicide layer, the silicon-oxy-nitride layer, and the second polysilicon layer is continuously formed over the interpoly dielectric layer. The defined photoresist layer is formed on the second polysilicon layer. A portion of the second polysilicon layer is etched, using the defined photoresist layer as a mask. Afterwards, the defined photoresist layer is removed. The polysilicon spacer is formed in the second polysilicon layer sidewall. The silicon oxide layer is deposited over the second polysilicon layer. Next, the silicon oxide layer is etched back to expose the second polysilicon layer.