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Drain implant

The major steps are labeled 1 to 5. However, there are severed intermediate steps also involved. At "1", the shcdlow trenches cire formed, source and drain implants were accomplished, diffusion barriers were formed from Ti/TiN and a dummy gate made from Si3N4 was deposited on... [Pg.326]

It should be noted that there is substantial applications overlap among the implantation segments. For example, medium current systems can run high dose source drain implants for pilot lines, albeit at low throughput. High energy... [Pg.214]

Step 8. The -type source and drain regions are created by As ion implantation. The As can penetrate the thin gate oxide, but not the thick field oxide or the polysihcon gate. The formation of the source and gate does not require a separate resist pattern, thus this technique is called self-aligning. [Pg.354]

Fig. 9. Fabrication sequence for an oxide-isolated -weU CMOS process, where is boron and X is arsenic. See text, (a) Formation of blanket pod oxide and Si N layer resist patterning (mask 1) ion implantation of channel stoppers (chanstop) (steps 1—3). (b) Growth of isolation field oxide removal of resist, Si N, and pod oxide growth of thin (<200 nm) Si02 gate oxide layer (steps 4—6). (c) Deposition and patterning of polysihcon gate formation of -source and drain (steps 7,8). (d) Deposition of thick Si02 blanket layer etch to form contact windows down to source, drain, and gate (step 9). (e) Metallisation of contact windows with W blanket deposition of Al patterning of metal (steps 10,11). The deposition of intermetal dielectric or final... Fig. 9. Fabrication sequence for an oxide-isolated -weU CMOS process, where is boron and X is arsenic. See text, (a) Formation of blanket pod oxide and Si N layer resist patterning (mask 1) ion implantation of channel stoppers (chanstop) (steps 1—3). (b) Growth of isolation field oxide removal of resist, Si N, and pod oxide growth of thin (<200 nm) Si02 gate oxide layer (steps 4—6). (c) Deposition and patterning of polysihcon gate formation of -source and drain (steps 7,8). (d) Deposition of thick Si02 blanket layer etch to form contact windows down to source, drain, and gate (step 9). (e) Metallisation of contact windows with W blanket deposition of Al patterning of metal (steps 10,11). The deposition of intermetal dielectric or final...
These processes are considerably more complex in actual CMOS fabrication. First, the lower layers of a CMOS stmcture typically have a twin-tub design which includes both PMOS and NMOS devices adjacent to each other (see Fig. 3b). After step 1, a mask is opened such that a wide area is implanted to form the -weU, followed by a similar procedure to create the -weU. Isolation between active areas is commonly provided by local oxidation of sihcon (LOCOS), which creates a thick field oxide. A narrow strip of lightly doped drain (LDD) is formed under the edges of the gate to prevent hot-carrier induced instabiUties. Passivation sidewalls are used as etch resists. A complete sequence of fabrication from wafer to packaged unit is shown in Figure 10. [Pg.354]

Conventional electronic devices are made on silicon wafers. The fabrication of a silicon MISFET starts with the diffusion (or implantation) of the source and drain, followed by the growing of the insulating layer, usually thermally grown silicon oxide, and ends with the deposition of the metal electrodes. In TFTs, the semiconductor is not a bulk material, but a thin film, so that the device presents an inverted architecture. It is built on an appropriate substrate and the deposition of the semiconductor constitutes the last step of the process. TFT structures can be divided into two families (Fig. 14-12). In coplanar devices, all layers are on the same side of the semiconductor. Conversely, in staggered structures gate and source-drain stand on opposing sides of the semiconductor layer. [Pg.257]

Ion Implantation- these plasma machines are used to form the various parts of the coupled transistors at voltages of 5 kV to 2 MV. These include retrograde well formation, gates, drains and sources. [Pg.327]

MOSFETT s, and silicon oxide is deposited. The source/drain positions where electrical contact is to be made to the MOSFETs are defined, using the oxide-removal mask and an etch process. For shallow trench isolation, anisotropic silicon etch, thermal oxidation, oxide fill and chemical mechanical leveling are the processes employed. For shallow source/drains formation, ion implantation techniques are still be used. For raised source/drains (as shown in the above diagram) cobalt silicide is being used instead of Ti/TLN silicides. Cobalt metal is deposited and reacted by a rapid thermal treatment to form the silicide. Capacitors were made in 1997 from various oxides and nitrides. The use of tantalmn pentoxide in 1999 has proven superior. Platinum is used as the plate material. [Pg.333]

Ge-ion implant in Si narrows the bandgap in the source region, which enhances hole flow in that region. The procedure improves performance by lowering the drain breakdown voltage. In a low-gate bias, this voltage improvement -1 eV has been achieved by an ion implantation method. [Pg.385]

See other pages where Drain implant is mentioned: [Pg.121]    [Pg.121]    [Pg.424]    [Pg.205]    [Pg.207]    [Pg.778]    [Pg.780]    [Pg.205]    [Pg.207]    [Pg.121]    [Pg.121]    [Pg.424]    [Pg.205]    [Pg.207]    [Pg.778]    [Pg.780]    [Pg.205]    [Pg.207]    [Pg.350]    [Pg.352]    [Pg.353]    [Pg.353]    [Pg.353]    [Pg.371]    [Pg.325]    [Pg.332]    [Pg.138]    [Pg.86]    [Pg.170]    [Pg.171]    [Pg.835]    [Pg.352]    [Pg.353]    [Pg.353]    [Pg.353]    [Pg.371]    [Pg.368]    [Pg.350]    [Pg.354]    [Pg.42]   
See also in sourсe #XX -- [ Pg.205 ]

See also in sourсe #XX -- [ Pg.205 ]



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Draining

Lightly doped drain implant

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Source/drain implant process

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