On the punchthrough phenomenon in submicron MOS transistors

As the channel length of MOS transistors reduces to the submicron dimension, the punchthrough becomes more of a surface-initiated and gate-controlled phenomenon. A surface diffusion current (I_sdif) originates from the injection of minority carriers from the source junction due to the combined effect of drain-induced-barrier-lowering (DIBL) and surface-band-bending (Δφ_so). The DIBL effect increases rapidly with decreasing channel length. In addition, the extracted Δφ_so from the punchthrough current indicates that surface space charges at the source edge shift from the accumulation/depletion mode for long submicron devices (≈0.62 μm) to the strong-inversion mode for deep submicron devices (≈0.12 μm). In general, I_sdif dominates over the low drain bias range and eventually converts to the bulk space-charge-limited current (I_scl) as the drain bias increases and the source/drain depletion regions connect. The drain bias for this conversion to occur strongly depends on the channel dimension. Only intermediate submicron devices (≈0.37 μm) in this study clearly show both the surface and bulk (space-charge-limited) punchthrough components. For long submicron devices, I_sdif essentially dominates, while for deep submicron devices, it converts rapidly to I_scl over the drain bias range investigated. A semi-empirical closed form equation is proposed to describe both I_sdif and I_scl and their merging over the entire range of drain bias     

SiGe source/drain structure for the suppression of theshort-channel effect of sub-0.1-μm p-channel MOSFETs

A bandgap engineering technique is proposed for the suppression of the short-channel effect (SCE) and its effectiveness is quantitatively calculated in the case of the SiGe source/drain structure with a device simulation. The drain-induced barrier lowering (DIBL) and the charge sharing are suppressed by the presence of the valence band discontinuity between the SiGe source/drain and Si channel. In order to obtain the full advantage of this structure, it is necessary to locate the SiGe layers both at the source/drain regions and the SiSe/Si interface at the pn junction or inside the channel region. The effectiveness increases with the increase of the valence band discontinuity (Ge concentration). As a result of the suppression of the SCE and the reduction of the minimum gate length, the drain current increases, and thus high-speed operation can be realized with this technique     

Improved low temperature characteristics of P-channel MOSFETs withSi1-xGex raised source and drain

P-channel metal-oxide-semiconductor field-effect transistors with Si_1-xGe_x raised source and drain (RSD) have been fabricated and further studied for low temperature applications. The Si _1-xGe_x RSD layer was selectively grown by ANELVA SRE-612 ultra-high vacuum chemical vapor deposition (UHVCVD) system. Compared to devices with conventional Si RSD, improved transconductance and specific contact resistance were obtained, and these improvements become even more dramatic with reducing channel length. Well-behaved short channel characteristics with reduced drain-induced barrier lowering (DIBL) and off-state leakage current are demonstrated on devices with 100 nm Si_1-xGe_x RSD, due to the resultant shallow junction and less implantation damage. Moreover, temperature measurements reveal that Si_1-xGe_x RSD devices show more dramatic improvement in device performance at low temperature (-50 °C) operation, which can be ascribed to the higher temperature sensitivity of the Si_1-xGe_x sheet resistance     

A high-performance polycrystalline silicon thin film transistorwith a silicon nitride gate insulator

We have fabricated a high performance polycrystalline silicon (poly-Si) thin film transistor (TFT) with a silicon-nitride (SiN_x ) gate insulator using three stacked layers: very thin laser of hydrogenated amorphous silicon (a-Si:H), SiN_x and laser annealed poly-Si. After patterning thin a-Si:H/SiN_x layers, gate, and source/drain regions were ion-doped and then Ni layer was deposited. This structure was annealed at 250°C to form a NiSi silicide phase. The low resistive Ni silicides were introduced as gate/source/drain electrodes in order to reduce the process steps. The poly-Si with a grain size of 250 nm and low resistance n⁺ poly-Si for ohmic contact were introduced to achieve a high performance TFT. The fabricated poly-Si TFT exhibited a field effect mobility of 262 cm²/Vs and a threshold voltage of 1 V     

Anomalous Ti SALICIDE gate to source/drain shorts induced by dry Sietch during TiSi2 local interconnect formation

A new failure mode was observed in a 0.5 μm version of the silicided amorphous-silicon contact and interconnect (SAC) technology. Massive PMOS gate to source/drain shorts were found. The cause is attributed to formation of Ti during the Si etch. The fluorinated Ti surface fails to form adequate TiN diffusion barrier during subsequent rapid thermal annealing (RTA) in N₂ or NH₃ ambient. Si diffuses from the polycrystalline Si gate and/or the p-type source/drain onto the spacer, reacts with Ti and forms resistive leakage paths. A blanket low-dose, low-energy As implant prior to Ti deposition corrects this problem without adversely changing device characteristics     

Hydrogen dilution effect on the properties of coplanar amorphoussilicon thin-film transistors fabricated by inductively-coupled plasmaCVD

The electrical and optical properties of the hydrogenated amorphous silicon (a-Si:H) films deposited by inductively-coupled plasma (ICP) chemical vapor deposition (CVD) with a variation of H₂ flow rate have been studied. The photosensitivity of a-Si:H is ~10⁷ when the H₂/SiH₄ ratio is between 3 and 8. With increasing H₂/SiH₄, the SiH₂ mode infrared absorption has a minimum at a H₂/SiH₄ ratio of 8. Coplanar a-Si:H thin-film transistors (TFT's) were fabricated using a triple layer of thin a-Si:H, silicon-nitride, and a-Si:H deposited by ICP-CVD using ion doping and low resistivity Ni silicide. After patterning the thin a-Si:H/silicon-nitride layers on the channel region, the gate and source/drain regions were ion-doped and then heated at 230°C to form Ni silicide layers. The low resistive Ni silicide formed on the a-Si:H reduces the offset length between gate and source/drain, leads to a coplanar a-Si:H TFT. The TFT exhibited a field effect mobility of 0.6 cm²/Vs and a threshold voltage of 2.3 V at the H₂/SiH₄ ratio of 8. The effect of H₂ dilution in SiH₄ on the coplanar a-Si:H TFT performance has been investigated. We found that the performance of the TFT is the best when the SiH₂ mode density in a-Si:H is the minimum. The coplanar TFT is very suitable for large-area, high density TFT displays because of its low parasitic capacitance between gate and source/drain contacts     

MOSFETs with ultrashallow junction and minimum drain area formed byusing solid-phase diffusion from SiGe

An advanced CMOS structure, in which a raised source/drain and contact windows formed over the field oxide, was fabricated. Ultrashallow junction formation using solid-phase diffusion from doped SiGe layers was used to fabricate MOSFETs. These MOSFETs demonstrated excellent short-channel characteristics and 70%-80%-reduced parasitic drain-junction capacitance. They have ultrashallow junctions with a depth of 25 nm and a low source/drain extension (SDE) resistance: 350 Ω/sq (NMOSFETs) and 390 Ω/sq (PMOSFETs). The isotropic diffused SDE structure was formed by using solid-phase diffusion, which could effectively form a shallow junction and a suitable overlap between gate and SDE. This structure results in good short-channel characteristics and high current drivability     

Submicrometer salicide CMOS devices with self-aligned shallow/deepjunctions

The use of triple-layer oxide/nitride/PETEOS (plasma-enhanced TEOS) gate spacer, CMOS (T-MOS) structure to form shallow/deep junctions with the deep junction self-aligned to the silicide layer on the source/drain area of submicrometer CMOS devices is discussed. Due to the disposable PETEOS spacer layer, only two masks (one for each channel) are needed to form this source/drain junction signature. A T-MOS structure of 0.5-μm physical gate length has been demonstrated with good device characteristics and ideal junction leakage properties. This T-MOS process, with its moderated doped drain (MDD) structure, is a promising device choice for deep-submicrometer CMOS devices     

Three-dimensional DIBL for shallow-trench isolated MOSFET's

This work presents a new phenomenon: the three-dimensional (3-D) DIBL effect. The effect is examined by studying the width-dependent punchthrough leakage of deep-submicron shallow-trench isolated (STI) MOSFET's. Different from previous works on STI, where phenomena are investigated in a low V_d range, the 3-D DIBL is based on analyses in the large V_d range. For STI process,the effect suppress DIBL and the suppression is more effective as scaling down device width. The phenomenon is a result of the 3-D electrostatic effect, which diverts drain fields away from channel into the gate electrode over field oxide region. The effect reduces the total drain fields penetrating through the channel into the source, and hence suppress the DIBL. A simple dipole theory describing the 3-D DIBL phenomenon is presented to extend the previous DIBL theory, which is based on two-dimensional (2-D) approach. Three-dimensional device simulations are used to obtain insights on electric field and surface potential to illustrate the physical basis for the 3-D DIBL theory     

Advanced model and analysis of series resistance for CMOS scalinginto nanometer regime. I. Theoretical derivation

An advanced series resistance model is developed to accurately predict source/drain (S/D) series resistance of complementary metal-oxide semiconductor (CMOS) in the nanometer regime. The series resistance is modeled by division into four resistance components named SDE-to-gate overlap, S/D extension, deep S/D, and silicide-diffusion contact resistance, considering the nonnegligible doping-dependent potential relationship in MOS accumulation region due to scaled supply voltage, current behavior related to heavily doped ultra-shallow source/drain extension (SDE) junction, polysilicon gate depletion effects (PDE), lateral and vertical doping gradient effect of SDE junction, silicide-diffusion contact structure, and high-κ dielectric sidewall. The proposed model well characterizes unique features of nanometer-scale CMOS and is useful for analyzing the effect of source/drain parameters on CMOS device scaling and optimization     

An Amorphous Silicon Local Interconnection (ASLI) CMOS with Self-Aligned Source/Drain and Its Electrical Characteristics

A CMOS device which has an extended heavily-doped amorphous silicon source/drain layer on the field oxide and an amorphous silicon local interconnection (ASLI) layer in the self-aligned source/drain region has been studied. The ASLI layer has some important roles of the local interconnections from the extended source/drain to the bulk source/drain and the path of the dopant diffusion sources to the bulk. The junction depth and the area of the source/drain can be controlled easily by the ASLI layer thickness. The device in this paper not only has very small area of source/drain junctions, but has very shallow junction depths than those of the conventional ones. The electrical characteristics of this device are as good as those of the conventional CMOS device. An operating speed, however, is enhanced significantly compared with the conventional ones, because the junction capacitance of the source/drain is reduced remarkably due to the very small area of source/drain junctions. For a 71-stage unloaded CMOS ring oscillator, 128 ps/gate has been obtained at power supply voltage of 3.3 V. Utilizing this proposed structure, a buried channel PMOS device for the deep submicron regime, known to be difficult to implement, can be fabricated easily.     

Fabrication of Schottky barrier MOSFETs using self-assembly CoSi2 nanopatterning and spacer gate technologies

A self-assembly patterning method for generation of epitaxial CoSi₂ nanostructures was used to fabricate 50 nm channel-length MOSFETs. The transistors have either a symmetric structure with Schottky source and drain or an asymmetric structure with n⁺-source and Schottky drain. The patterning technique is based on anisotropic diffusion of Co/Si atoms in a strain field during rapid thermal oxidation. The strain field is generated along the edges of a mask consisting of 20 nm SiO₂ and 300 nm Si₃N₄. During rapid thermal oxinitridation (RTON) of the masked silicide structure, a well-defined separation of the silicide layer forms along the edge of the mask. These highly uniform gaps define the channel region of the fabricated device. The separated silicide layers act as metal source and drain. A poly-Si spacer was used as the gate contact. The asymmetric transistor was fabricated by ion implantation into the unprotected CoSi₂ layer and a subsequent out-diffusion process to form the n⁺-source. I–V characteristics of both the symmetric and asymmetric transistor structures have been investigated.     

A capacitance-based method for experimental determination ofmetallurgical channel length of submicron LDD MOSFETs

A capacitance based method for determining L_met the metallurgical channel length of MOSFET, is proposed in this paper. This method has been extensively evaluated via two-dimensional numerical device simulation of MOSFETs with different source/drain tip and channel impurity concentration profiles as well as different gate oxide thicknesses. For all the impurity profiles tested, results demonstrated that the accuracy in extracting L_met of MOSFETs with gate oxides thinner than 100 Å is better than 110 Å. This method is applicable even when there is significant source/drain reoxidation induced gate oxide thickening, as long as the gate oxide thickening is not extended into the region directly above the metallurgically defined channel region. Unlike the determination of L_eff, the effective electrical channel length, from the drain current, L_met is extracted from capacitance data and the extraction is free from complications that can be introduced by incomplete removal of the resistive effects associated with contacts and the lightly doped source/drain region. Extensive measurements were performed on MOSFETs of different technologies. It is shown that the measurement is accurately repeatable and no device stressing is experienced over the required bias range. The L_met and L_eff extracted from measured capacitance and drain current data are compared. Results showed that L _met is typically 700 to 1200 Å shorter for submicron MOS technologies, but it tracks with L_eff, i.e. a shorter L _met corresponds to a shorter L_eff     

$hbox{In}_{0.53}hbox{Ga}_{0.47}hbox{As}$ Channel MOSFETs With Self-Aligned InAs Source/Drain Formed by MEE Regrowth

Abstract-We report Al₂O₃Zln_0.53Ga_0.47As MOSFETs having both self-aligned in situ Mo source/drain ohmic contacts and self-aligned InAs source/drain n⁺ regions formed by MBE regrowth. The device epitaxial dimensions are small, as is required for 22-nm gate length MOSFETs; a 5-nm In_0.53Ga_0.47As channel with an In_0.4sAl_0.52As back confinement layer and the n⁺⁺ source/drain junctions do not extend below the 5-nm channel. A device with 200-nm gate length showed I_D = 0.95 mA/mum current density at V_GS = 4.0 V and g_m = 0.45 mS/mum peak transconductance at V_DS = 2.0 V.     

Optimum design of n+-n-double-diffused drain MOSFET to reduce hot-carrier emission

Channel electric field reduction using an n⁺-n^-double-diffused drain MOS transistor to suppress hot-carrier emission is investigated. The double-diffused structure consists of a deep low-concentration P region and a shallow high-concentration As region. The channel electric field strongly depends on such process and device parameters as the length of the n^-diffusion region, drain junction depth, gate oxide thickness, gate length, applied voltage, and P implant energy. The optimum condition for a double-diffused structure is determined based on those parameter dependences of the channel electric field. The results of the optimum drain impurity profile to give the minimum channel electric field are obtained when the maximum lateral electric field is located at the boundary between the P region and the As region. The hot-carrier immunity of MOSFET and test circuits are improved by two orders of magnitude and one order of magnitude, respectively, under the optimum conditions.     

n+/p+ Gate Bulk FinFETs With Locally Separated Channel Structure for Sub-50-nm DRAM Cell Transistors

We proposed a new p⁺/n⁺ poly-Si gate bulk fin-type field-effect transistor that has two channel fins separated locally by a shallow trench filled with oxide or p⁺ polygate. Key device characteristics were investigated by changing the n⁺ poly-Si gate length La, the material filling the trench, and the width and length of the trench at a given gate length L_g. It was shown that the trench filled with p⁺ poly-Si gate should not be contacted with the source/drain diffusion region to achieve an excellent I_on/I_off (> 1010) that is suitable for sub-50-nm dynamic random access memory cell transistors. Based on the aforementioned device structure, we designed reasonable Ls/Lg and channel fin width W_cfin at given L_g 's of 30, 40, and 50 nm.     

A new p-channel MOSFET with large-tilt-angle implanted punchthroughstopper (LATIPS)

A buried-channel p-MOSFET with a large-tile-angle implanted punchthrough stopper (LATIPS) is described. In this device the n⁺ LATIPS region was successfully realized adjacent to the p⁺ source/drain, even without a sidewall spacer, by taking advantage of the n⁺ large-tilt-angle implant. In spite of the relatively deep p⁺ junction of 0.2-μm depth and the low n-well concentration of 1×10¹⁶ cm^-3, the 0.5-μm LATIPS device (with corresponding channel length of 0.3 μm) achieved high punchthrough resistance, e.g. a low subthreshold swing of 95 mV/decade with a high transconductance of 135 mS/mm     

A new 0.25-μm recessed-channel MOSFET with selectivelyhalo-doped channel and deep graded source/drain

To improve the performance and reliability of deep submicron MOS devices, a gate-recessed MOSFET (GR-MOSFET), which has a selectively halo-doped recessed channel and a deep graded source/drain formed without counterdoping, is proposed. The GR-MOS structure, which adopts a new doping concept, eliminates the tradeoff between drain-induced barrier lowering (DIBL) and hot-carrier effect, which are important to deep submicron device design. It also reduces the V_T lowering effect and the lateral electric field at the drain. A 0.25-μm GR-MOSFET with a 10-nm gate oxide has exhibited 15% higher transconductance and 10% increased saturation current at V_D=V _G=3.3 V, 1 V higher BV_DSS, and six times less substrate current compared with an LDD-MOSFET of the same device dimensions     

An accurate gate length extraction method for sub-quarter micronMOSFET's

By comparing measured and simulated gate-to-source/drain capacitances, C_gds, an accurate gate length extraction method is proposed for sub-quarter micron MOSFET's applications. We show that by including the 2-D field effect on the fringing capacitance, the polysilicon depletion and the quantum-well effects in the C_gds simulation, the polysilicon gate length, L_poly, can be accurately determined for device lengths down to the 0.1 μm regime. The accuracy of this method approaches that of cross-sectional TEM on the device under test, but without destroying the device. Furthermore, we note that as a result of accurate L_poly extraction, the source/drain lateral diffusion length, L_diff , and effective channel length, L_eff, can also be determined precisely. The accuracy of L_diff is confirmed by examining their consistency with experimentally obtained 2-D source/drain profile     

Ga2O3(Gd2O3)/InGaAsenhancement-mode n-channel MOSFETs

We have demonstrated the first Ga₂O₃(Gd₂O₃) insulated gate n-channel enhancement-mode In_0.53Ga_0.47As MOSFET's on InP semi-insulating substrate. Ga₂O₃(Gd₂ O₃) was electron beam deposited from a high purity single crystal Ga₅Gd₃O₁₂ source. The source and drain regions of the device were selectively implanted with Si to produce low resistance ohmic contacts. A 0.75-μm gate length device exhibits an extrinsic transconductance of 190 mS/mm, which is an order of magnitude improvement over previously reported enhancement-mode InGaAs MISFETs. The current gain cutoff frequency, f_t, and the maximum frequency of oscillation, f_max, of 7 and 10 GHz were obtained, respectively, for a 0.75×100 μm² gate dimension device at a gate voltage of 3 V and drain voltage of 2 V