Patent application number | Description | Published |
20080246056 | SILICIDE FORMATION FOR eSiGe USING SPACER OVERLAPPING eSiGe AND SILICON CHANNEL INTERFACE AND RELATED PFET - Methods of forming a suicide in an embedded silicon germanium (eSiGe) source/drain region using a suicide prevention spacer overlapping an interface between the eSiGe and the silicon channel, and a related PFET with an eSiGe source/drain region and a compressive stress liner in close proximity to a silicon channel thereof, are disclosed. In one embodiment, a method includes providing a gate having a nitrogen-containing spacer adjacent thereto and an epitaxially grown silicon germanium (eSiGe) region adjacent to a silicon channel of the gate; removing the nitrogen-containing spacer that does not extend over the interface between the eSiGe source/drain region and the silicon channel; forming a single silicide prevention spacer about the gate, the single silicide prevention spacer overlapping the interface; and forming the silicide in the eSiGe source/drain region using the single silicide prevention spacer to prevent the silicide from forming in at least an extension area of the silicon channel. | 10-09-2008 |
20080303060 | Semiconductor devices and methods of manufacturing thereof - Semiconductor devices and methods of manufacturing thereof are disclosed. In a preferred embodiment, a method of manufacturing a semiconductor device includes providing a semiconductor wafer, forming a first material on the semiconductor wafer, and affecting the semiconductor wafer with a manufacturing process. The manufacturing process inadvertently causes a portion of the first material to be removed. The portion of the first material is replaced with a second material. | 12-11-2008 |
20090135655 | Embedded Flash Memory Devices on SOI Substrates and Methods of Manufacture Thereof - Flash memory device structures and methods of manufacture thereof are disclosed. The flash memory devices are manufactured on silicon-on-insulator (SOI) substrates. Shallow trench isolation (STI) regions and the buried oxide layer of the SOI substrate are used to isolate adjacent devices from one another. The methods of manufacture require fewer lithography masks and may be implemented in stand-alone flash memory devices, embedded flash memory devices, and system on a chip (SoC) flash memory devices. | 05-28-2009 |
20090294807 | Methods of Fabricating Transistors and Structures Thereof - Methods of fabricating transistors, semiconductor devices, and structures thereof are disclosed. In one embodiment, a method of fabricating a transistor includes forming a gate dielectric over a workpiece, and forming a gate over the gate dielectric. Sidewall spacers are formed over the gate dielectric and the gate, the sidewall spacers comprising germanium oxide (GeO or GeO | 12-03-2009 |
20090294866 | Transistor Fabrication Methods and Structures Thereof - Methods of fabricating transistors and semiconductor devices and structures thereof are disclosed. In one embodiment, a method of fabricating a transistor includes forming a gate dielectric over a workpiece, forming a gate over the gate dielectric, and forming a stress-inducing material over the gate, the gate dielectric, and the workpiece. Sidewall spacers are formed from the stress-inducing material on sidewalls of the gate and the gate dielectric. | 12-03-2009 |
20090294986 | Methods of Forming Conductive Features and Structures Thereof - Methods of forming features and structures thereof are disclosed. In one embodiment, a method of forming a feature includes forming a first material over a workpiece, forming a first pattern for a lower portion of the feature in the first material, and filling the first pattern with a sacrificial material. A second material is formed over the first material and the sacrificial material, and a second pattern for an upper portion of the feature is formed in the second material. The sacrificial material is removed. The first pattern and the second pattern are filled with a third material. | 12-03-2009 |
20100029072 | Methods of Forming Electrical Interconnects Using Thin Electrically Insulating Liners in Contact Holes - Methods of forming integrated circuit devices include forming an electrically insulating layer having a contact hole therein, on a substrate, and then depositing an electrically insulating liner onto a sidewall of the contact hole using an atomic layer deposition (ALD) technique. This electrically insulating liner, which may include gelatinous silica or silicon dioxide, for example, may be deposited to a thickness in a range from 40 Å to 100 Å. A portion of the electrically insulating liner is then removed from a bottom of the contact hole and a barrier metal layer is then formed on the electrically insulating liner and on a bottom of the contact hole. The step of forming the barrier metal layer may be followed by filling the contact hole with a metal interconnect. | 02-04-2010 |
20100096685 | Strained Semiconductor Device and Method of Making Same - In a method of making a semiconductor device, a gate dielectric is formed over the semiconductor body. A floating gate is formed over the gate dielectric, an insulating region over the floating gate, and a control gate over the insulating region. The gate dielectric, floating gate, insulating region, and control gate constitute a gate stack. A stress is caused in the gate stack, whereby the band gap of the gate dielectric is changed by the stress. | 04-22-2010 |
20100149882 | Methods of Operating Embedded Flash Memory Devices - Flash memory device structures and methods of manufacture thereof are disclosed. The flash memory devices are manufactured on silicon-on-insulator (SOI) substrates. Shallow trench isolation (STI) regions and the buried oxide layer of the SOI substrate are used to isolate adjacent devices from one another. The methods of manufacture require fewer lithography masks and may be implemented in stand-alone flash memory devices, embedded flash memory devices, and system on a chip (SoC) flash memory devices. | 06-17-2010 |
20100193867 | Silicided Semiconductor Structure and Method of Forming the Same - A preferred embodiment includes a method of manufacturing a fuse element that includes forming a polysilicon layer over a semiconductor structure, doping the polysilicon layer with carbon or nitrogen, depositing a metal over the polysilicon layer; and annealing the metal and polysilicon layer to form a silicide in an upper portion of the polysilicon layer. | 08-05-2010 |
20100297818 | Semiconductor Devices Having pFET with SiGe Gate Electrode and Embedded SiGe Source/Drain Regions and Methods of Making the Same - In a method of making a semiconductor device, a first gate stack is formed on a substrate at a pFET region, which includes a first gate electrode material. The source/drain regions of the substrate are etched at the pFET region and the first gate electrode material of the first gate stack is etched at the pFET region. The etching is at least partially selective against etching oxide and/or nitride materials so that the nFET region is shielded by a nitride layer (and/or a first oxide layer) and so that the spacer structure of the pFET region at least partially remains. Source/drain recesses are formed and at least part of the first gate electrode material is removed by the etching to form a gate electrode recess at the pFET region. A SiGe material is epitaxially grown in the source/drain recesses and in the gate electrode recess at the pFET region. The SMT effect is achieved from the same nitride nFETs mask. | 11-25-2010 |
20110006373 | Transistor Structure - Methods of fabricating transistors and semiconductor devices and structures thereof are disclosed. In one embodiment, a method of fabricating a transistor includes forming a gate dielectric over a workpiece, forming a gate over the gate dielectric, and forming a stress-inducing material over the gate, the gate dielectric, and the workpiece. Sidewall spacers are formed from the stress-inducing material on sidewalls of the gate and the gate dielectric. | 01-13-2011 |
20110175148 | Methods of Forming Conductive Features and Structures Thereof - Methods of forming features and structures thereof are disclosed. In one embodiment, a method of forming a feature includes forming a first material over a workpiece, forming a first pattern for a lower portion of the feature in the first material, and filling the first pattern with a sacrificial material. A second material is formed over the first material and the sacrificial material, and a second pattern for an upper portion of the feature is formed in the second material. The sacrificial material is removed. The first pattern and the second pattern are filled with a third material. | 07-21-2011 |
20120126305 | Strained Semiconductor Device and Method of Making Same - In a method of making a semiconductor device, a gate dielectric is formed over the semiconductor body. A floating gate is formed over the gate dielectric, an insulating region over the floating gate, and a control gate over the insulating region. The gate dielectric, floating gate, insulating region, and control gate constitute a gate stack. A stress is caused in the gate stack, whereby the band gap of the gate dielectric is changed by the stress. | 05-24-2012 |
20120196432 | Method for Manufacturing Contact Holes in CMOS Device Using Gate-Last Process - The present invention provides a method for manufacturing contact holes in a CMOS device by using a gate-last process, comprising: forming high-K dielectrics/metal gates (HKMG) of a first type MOS; forming and metalizing lower contact holes of the source/drain of a first type MOS and a second type MOS as well as forming HKMG of a second type MOS simultaneously, wherein the lower contact holes of the source/drain are filled with the same material as that used by the metal gate of the second type MOS; forming and metalizing contact holes of metal gates of a first type MOS and a second type MOS as well as upper contact holes of the source/drain, wherein the upper contact holes of the source/drain are aligned with the lower contact holes of the source/drain. The method reduces the difficulty of contact hole etching and metal deposition, simplifies the process steps, and increases the reliability of the device. | 08-02-2012 |
20120322172 | METHOD FOR MONITORING THE REMOVAL OF POLYSILICON PSEUDO GATES - The present invention discloses a method for monitoring the removal of a polycrystalline silicon dummy gate, comprising the steps of: forming a polycrystalline silicon dummy gate structure on a surface of a wafer; determining a measurement target and an error range of mass of the wafer; and measuring the mass of the wafer by a mass measurement tool after polycrystalline silicon dummy gate removal to determine whether the polycrystalline silicon dummy gate has been completely removed. According to the measurement method of the present invention, the full wafer may be quickly and accurately measured without requiring a specific test structure, to effectively monitor and determine whether the polysilicon dummy gate is thoroughly removed, meanwhile said measurement method gives feedback directly, quickly and accurately without causing any damage to the wafer. | 12-20-2012 |
20130015510 | Transistor, Semiconductor Device, and Method for Manufacturing the SameAANM Yan; JiangAACI NewburghAAST NYAACO USAAGP Yan; Jiang Newburgh NY USAANM Zhao; LichuanAACI BeijingAACO CNAAGP Zhao; Lichuan Beijing CN - The invention provides a transistor, a semiconductor device and a method for manufacturing the same. The method for manufacturing a transistor comprises: defining an active area on a semiconductor substrate, forming a dummy gate stack on the active area, primary spacers surrounding said dummy gate stack, and an insulating layer surrounding said primary spacers, and forming source/drain regions embedded in said active area; removing the dummy gate in said dummy gate stack to form a first recessed portion surrounded by the primary spacers; filling Cu simultaneously in said first recessed portion and in the source/drain contact holes penetrating said insulating layer to form a gate and source/drain contacts. By filling the gate and the source/drain contact holes with the metal Cu simultaneously in the Gate Last structure, the gate serial resistance and the source/drain contact holes resistance in the Gate Last process are decreased. Besides, the effect of metal filling is improved in small scale, and the process complexity and difficulty is efficiently decreased. | 01-17-2013 |
20130020618 | SEMICONDUCTOR DEVICE, FORMATION METHOD THEREOF, AND PACKAGE STRUCTURE - A semiconductor device, a formation method thereof, and a package structure are provided. The semiconductor device comprises: a semiconductor substrate in which a metal-oxide-semiconductor field-effect transistor (MOSFET) is formed; a dielectric layer, provided on the semiconductor substrate and covering the MOSFET, wherein a plurality of interconnection structures are formed in the dielectric layer; and at least one heat dissipation path, embedded in the dielectric layer between the interconnection structures, for liquid or gas to circulate in the heat dissipation path, wherein openings of the heat dissipation path are exposed on the surface of the dielectric layer. The present invention can improve heat dissipation efficiency, and prevent chips from overheating. | 01-24-2013 |
20130059434 | METHOD FOR MANUFACTURING ELECTRODES AND WIRES IN GATE LAST PROCESS - The present invention provides a method for manufacturing a gate electrode and a contact wire simultaneously in a gate last process, comprising the steps of: forming a gate trench in an inter layer dielectric layer on a substrate; forming a filling layer in the gate trench and on the inter layer dielectric layer; etching the filling layer and the inter layer dielectric layer to expose the substrate, to thereby form a source/drain contact hole; removing the filling layer to expose the gate trench and the source/drain contact hole; forming metal silicide in the source/drain contact hole; depositing a gate dielectric layer and a metal gate in the gate trench; filling metal in the gate trench and the source/drain contact hole; and planarizing the filled metal. In accordance with the manufacturing method of the present invention, the gate electrode wire will be made of the same metal material as the contact hole such that the two can be manufactured by one CMP process. Such a design has the advantages of simplifying complexity of process integration on one hand and greatly strengthening control of defects by CMP process on the other hand, thereby avoiding the defects like erosion and dishing that may be produced between different metal materials. | 03-07-2013 |
20130059435 | Method of Manufacturing Dummy Gates in Gate Last Process - The present invention provides a method of manufacturing a dummy gate in a gate last process, which comprises the steps of forming a dummy gate material layer and a hard mask material layer sequentially on a substrate; etching the hard mask material layer to form a top-wide-bottom-narrow hard mask pattern; dry etching the dummy gate material layer using the hard mask pattern as a mask to form a top-wide-bottom-narrow dummy gate. According to the dummy gate manufacturing method of the present invention, instead of vertical dummy gates used conventionally, top-wide-bottom-narrow trapezoidal dummy gates are formed, and after removing the dummy gates, trapezoidal trenches can be formed. It facilitates the subsequent filling of the high-k or metal gate material and enlarges the window for the filling process; as a result, the device reliability will be improved. | 03-07-2013 |
20130082350 | SILICON-ON-INSULATOR CHIP HAVING MULTIPLE CRYSTAL ORIENTATIONS - A silicon-on-insulator device having multiple crystal orientations is disclosed. In one embodiment, the silicon-on-insulator device includes a substrate layer, an insulating layer disposed on the substrate layer, a first silicon layer, and a strained silicon layer. The first silicon layer has a first crystal orientation and is disposed on a portion of the insulating layer, and the strained silicon layer is disposed on another portion of the insulating layer and has a crystal orientation different from the first crystal orientation. | 04-04-2013 |
20130320401 | Mixed Orientation Semiconductor Device and Method - A method of making a semiconductor device begins with a semiconductor wafer that includes a first semiconductor layer overlying a second semiconductor layer. A first trench is etched in the semiconductor wafer. The first trench is filled with insulating material. A second trench is etched within the first trench and through the insulating material, such that insulating material remains along sidewalls of the first trench. The second trench exposes a portion of the second insulating layer. A semiconductor layer can then be grown within the second trench using the second semiconductor layer as a seed layer. | 12-05-2013 |
20140015062 | Method for Forming Gate Structure, Method for Forming Semiconductor Device, and Semiconductor Device - An embodiment of the present disclosure provides a method for forming a gate structure, comprising: providing a substrate, where the substrate includes a nMOSFET area and a pMOSFET area, each of the nMOSFET area and the pMOSFET area has a gate trench, and each of the gate trenches is provided at a bottom portion with a gate dielectric layer; forming a gate dielectric capping layer on a surface of the substrate; forming an oxygen scavenging element layer on the gate dielectric capping layer; forming an etching stop layer on the oxygen scavenging element layer; forming a work function adjustment layer on the etching stop layer; performing metal layer deposition and annealing process to fill the gate trenches with a metal layer; and removing the metal layer outside the gate trenches. | 01-16-2014 |
20140015068 | Gate Structure, Semiconductor Device and Methods for Forming the Same - The disclosure relates to a gate structure, a semiconductor device and methods for forming the same. An embodiment of the disclosure provides a method for forming a gate structure, including: providing a substrate; forming an interface layer on the substrate; forming a gate dielectric layer on the interface layer; forming a gate dielectric capping layer on the gate dielectric layer; forming an etching stop layer on the gate dielectric capping layer; forming an oxygen scavenging element layer on the etching stop layer; forming an oxygen scavenging element capping layer on the oxygen scavenging element layer; performing Post-Metallization Annealing; performing etching until the etching stop layer is exposed; forming a work function adjustment layer on the etching stop layer; and forming a gate layer on the work function adjustment layer. | 01-16-2014 |
20140273426 | Method for Manufacturing Dummy Gate in Gate-Last Process and Dummy Gate in Gate-Last Process - A method for manufacturing a dummy gate in a gate-last process and a dummy gate in a gate-last process are provided. The method includes: providing a semiconductor substrate; growing a gate oxide layer on the semiconductor substrate; depositing bottom-layer amorphous silicon on the gate oxide layer; depositing an ONO structured hard mask on the bottom-layer amorphous silicon; depositing top-layer amorphous silicon on the ONO structured hard mask; depositing a hard mask layer on the top-layer amorphous silicon, and trimming the hard mask layer so that the trimmed hard mask layer has a width less than or equal to 22 nm; and etching the top-layer amorphous silicon, the ONO structured hard mask and the bottom-layer amorphous silicon in accordance with the trimmed hard mask layer, and removing the hard mask layer and the top-layer amorphous silicon. | 09-18-2014 |
20140332958 | Method for Manufacturing Dummy Gate in Gate-Last Process and Dummy Gate in Gate-Last Process - A method for manufacturing a dummy gate in a gate-last process is provided. The method includes: providing a semiconductor substrate; growing a gate oxide layer on the semiconductor substrate; depositing bottom-layer amorphous silicon on the gate oxide layer; depositing an ONO structured hard mask on the bottom-layer amorphous silicon; depositing top-layer amorphous silicon on the ONO structured hard mask; depositing a hard mask layer on the top-layer amorphous silicon; forming photoresist lines having a width ranging from 32 nm to 45 nm on the hard mask layer; and etching the hard mask layer, the top-layer amorphous silicon, the ONO structured hard mask and the bottom-layer amorphous silicon in accordance with the photoresist lines, and removing the photoresist lines, the hard mask layer and the top-layer α-Si. Correspondingly, a dummy gate in a gate-last process is also provided. | 11-13-2014 |
20150035087 | Method for Manufacturing Dummy Gate in Gate-Last Process and Dummy Gate in Gate-Last Process - A method for manufacturing a dummy gate in a gate-last process and a dummy gate in a gate-last process are provided. The method includes: providing a semiconductor substrate; growing a gate oxide layer on the semiconductor substrate; depositing bottom-layer amorphous silicon on the gate oxide layer; depositing an ONO structured hard mask on the bottom-layer amorphous silicon; depositing top-layer amorphous silicon on the ONO structured hard mask; depositing a hard mask layer on the top-layer amorphous silicon; forming photoresist lines on the hard mask layer, and trimming the formed photoresist lines so that the trimmed photoresist lines a width less than or equal to 22 nm; and etching the hard mask layer, the top-layer amorphous silicon, the ONO structured hard mask and the bottom-layer amorphous silicon in accordance with the trimmed photoresist lines, and removing the photoresist lines, the hard mask layer and the top-layer amorphous silicon. | 02-05-2015 |