Effects of post-deposition anneal on the electrical properties ofSi3N4 gate dielectric

The effects of postdeposition anneal of chemical vapor deposited silicon nitride are studied. The Si₃N₄ films were in situ annealed in either H₂(2%)/O₂ at 950°C or N₂O at 950°C in a rapid thermal oxidation system. It is found that an interfacial oxide was grown at the Si₃N₄/Si interface by both postdeposition anneal conditions. This was confirmed by thickness measurement and X-ray photoelectronic spectroscopy (XPS) analysis. The devices with H₂ (2%)/O₂ anneal exhibit a lower gate leakage current and improved reliability compared to that of N₂O anneal. This improvement is attributed to a greater efficiency of generating atomic oxygen in the presence of a small amount of hydrogen, leading to the elimination of structural defects in the as-deposited Si₃N ₄ film by the atomic oxygen. Good drivability is also demonstrated on a 0.12 μm n-MOSFET device     

Formation of high quality storage capacitor dielectrics by in-siturapid thermal reoxidation of Si3N4 films inN2O ambient

This letter reports on a novel reoxidation technique for SiO₂ /Si₃N₄ (ON) stacked films by using N₂ O as oxidant. Effect of in-situ rapid thermal N₂O reoxidation (RTNO) on the electrical characteristics of thin ON stacked films are studied and compared with those of in-situ rapid thermal. O ₂ reoxidation (RTO). Prior to reoxidation, the Si₃N₄ film was deposited by rapid thermal chemical vapor deposition (RT-CVD) using SiH₄ and NH₃. Results show that RTNO of the Si₃N₄ films significantly improves electrical characteristics of ON stacked films in terms of lower leakage current, suppressed charge trapping, reduced defect density and improved time-dependent-dielectric-breakdown (TDDB), as compared to RTO of the Si₃N₄ films     

Novel capacitor process using diffusion barrier rounded by Si3N4 spacer for high density FRAM device

A novel capacitor process was successfully implemented in 4 Mb FRAM device by developing a barrier layer rounded by Si₃N₄ spacer (BRS) scheme. Using this process, it is possible to eliminate an undesired barrier etching damage, which is a major role in degrading ferroelectric properties. The novel capacitor process was generated by etching an Ir barrier layer and rounding the barrier by a Si₃N₄ spacer before preparing Pb(Zr _1-xTi_x)O₃ (PZT) films. It was observed that uniform sol-gel derived PZT films were prepared on the patterned Ir substrate by using Si₃N₄ spacer, which provides a smooth edge of the patterned cell. The contact resistance between bottom electrode and polysilicon plug after full integration was monitored below 700 Ω per contact with contact size 0.6×0.6 (μm²). Compared to the ferroelectric capacitor damaged by barrier etching, the novel Pb(Zr_1-xTi_x)O₃ (PZT) capacitor exhibited a well-saturated Q-V curve. The fully processed novel capacitor having 1.2×1.2 (μm²) effective area displayed remnant polarization of 14 (μC/cm²) at an operating voltage of 3.0 V. The BRS ferroelectric capacitor showed a reliable retention property until 100 h at 125°C. Same state retention (Qss) was stable with time up to 100 h while opposite state retention (Qos) showed a log-linear decay rate at 125°C thermal stress     

High efficiency polycrystalline silicon solar cells using lowtemperature PECVD process

Conventionally directionally solidified (DS) and silicon film (SF) polycrystalline silicon solar cells are fabricated using gettering and low temperature plasma enhanced chemical vapor deposition (PECVD) passivation. Thin layer (~10 nm) of PECVD SiO₂ is used to passivate the emitter of the solar cell, while direct hydrogen rf plasma and PECVD silicon nitride (Si₃N₄) are implemented to provide emitter and bulk passivation. It is found in this work that hydrogen rf plasma can significantly improve the solar cell blue and long wavelength responses when it is performed through a thin layer of PECVD Si₃N₄. High efficiency DS and SF polycrystalline silicon solar cells have been achieved using a simple solar cell process with uniform emitter, Al/POCl₃ gettering, hydrogen rf plasma/PECVD Si₃N₄ and PECVD SiO₂ passivation. On the other hand, a comprehensive experimental study of the characteristics of the PECVD Si₃N₄ layer and its role in improving the efficiency of polycrystalline silicon solar cells is carried out in this paper. For the polycrystalline silicon used in this investigation, it is found that the PECVD Si₃N₄ layer doesn't provide a sufficient cap for the out diffusion of hydrogen at temperatures higher than 500°C. Low temperature (⩽400°C) annealing of the PECVD Si₃N ₄ provides efficient hydrogen bulk passivation, while higher temperature annealing relaxes the deposition induced stress and improves mainly the short wavelength (blue) response of the solar cells     

Low threshold current GaAs/AlGaAs GRIN-SCH lasers grown bymolecular beam epitaxy on Si3N4 masked substrates

High-performance single-quantum-well graded-refractive index separate confinement heterostructure (SQW GRINSCH) laser have been grown by molecular beam epitaxy on Si₃N₄ patterned GaAs (100) substrates. Lasers grown on stripe windows orientated in the [011] direction have optical waveguiding and current confinement supplied by facetting occurring during growth. Lasers fabricated on 10 μm wide Si ₃N₄ openings have threshold currents as low as 15 mA for a 500 μm-long cavity. The current density required to reach optical transparency is 144 A/cm²; an internal quantum efficiency of 81%, and a peak optical power of 70 mW per facet has been obtained. Device performance comparable to ridge lasers is observed in a self-aligned laser process     

The degradation of TDDB characteristics of Si02/Si3N4/Si02 stacked films caused by surfaceroughness of Si3N4 films [DRAMs]

The effect of surface roughness of Si₃N₄ films on time-dependent dielectric breakdown (TDDB) characteristics of SiO₂/Si₃N₄/SiO₂ (ONO) stacked films was investigated. The surface roughness of Si₃N ₄ films-was found to become higher with increasing deposition temperature and to cause the degradation of TDDB characteristics of ONO films in DRAMs. A local thinning of ONO films, evaluated from the TDDB characteristics, agreed with the surface roughness measured by atomic force microscopy (AFM) and cross-sectional transmission electron microscopy (XTEM). Dependence of time to breakdown of ONO films on the deposition conditions was interpreted by electric field intensification due to the surface roughness of Si₃N₄ films     

Oxidized Ta2O5/Si3N4dielectric films on poly-crystalline Si for dRAMs

A dielectric film technology characterized by a novel multilayer structure formed by oxidation of Ta₂O₅/Si₃ N₄ films on polysilicon has been developed to realize high-density dRAMs. The dry oxidation of the Ta₂O₅/Si₃N₄ layers was performed at temperatures higher than 900°C. This film has a capacitance per unit area from 5.5 to 6.0 fF/ μm², which is equivalent to that of a 6.0- to 6.5-nm-thick SiO₂. The leakage current at an effective electric field of 5 MV/cm is less than 10^-9 A/cm². Under such an electric field, the extrapolated time to failure for 50% cumulative failure can be as high as 1000 years     

A novel waveguided polarization mode splitter using refractiveindex changes induced by superlattice disordering

The operating principle of our polarization mode splitter is based on the polarization-dependent refractive index changes induced by disordering InGaAs/InP superlattices. We disordered superlattices by the Si₃N₄ cap-annealing method and measured the near-field patterns to confirm that the device functioned properly at a wavelength of 1.52 μm. The crosstalk was about -10 dB. We should be able to improve the characteristics of this device by optimizing its structure. This device requires no electrical control and will be very suitable for semiconductor monolithic integrated circuits     

Electrical Characteristics of Memory Devices With a High- k HfO2 Trapping Layer and Dual SiO2/Si3N4 Tunneling Layer

A novel device structure with a high-k HfO₂ charge storage layer and dual tunneling layer (DTL) (SiO₂/Si₃N₄) is presented in this paper. Combining advantages of the high trapping efficiency of high-k materials and enhanced charge injection from the substrate through the DTL, the device achieves a fast program/erase speed and a large memory window. The device demonstrates excellent retention due to its physically thick DTL and also improved endurance without any increase of programming V_th throughout the cyclic test as compared with SONOS Flash memory devices using an Si₃N₄ trapping layer.     

Electrical characteristics of B-implanted p-channelMNOS transistors

Boron ions (¹¹B⁺ of 3·7 to 7·4 × 10¹¹/cm² were implanted at 60–120 keV into the channel region of p-channel MNOS double layer insulated gate field effect transistors through 920–940 Å of SiO₂ and various thicknesses (300–1800 Å) of Si₃N₄ deposited on SiO₂. Subsequent annealing was performed in a nitrogen atmosphere at 1000°C for 30 min. Acceleration energy, implant dose and Si₃N₄ thickness dependences of the shift of the threshold voltage showed good agreement with the calculated results based on Ishiwara and Furukawa's theory for distribution of implanted atoms in the double layered substrate, using the projected ranges and standard deviations larger than LSS predictions by the factor of 1·2 for SiO₂ and 1·3 for Si₃N₄, respectively. The results on the gain terms and the breakdown voltages were qualitatively the same as those of ¹¹B⁺-implanted p-channel MOS transistors.     

Formation of high quality ultrathin oxide/nitride (ON) stackedcapacitors by in situ multiple rapid thermal processing [DRAMcells]

High quality, ultrathin (<30 Å) SiO₂/Si₃ N₄ (ON) stacked film capacitors have been fabricated by in situ rapid-thermal multiprocessing. Si₃N₄ film was deposited on the RTN-treated poly-Si by rapid-thermal chemical vapor deposition (RTCVD) using SiH₄ and NH₃, followed by in situ low pressure rapid-thermal reoxidation in N₂O (LRTNO) or in O₂ (LRTO) ambient. While the use of low pressure reoxidation suppresses severe oxidation of ultrathin Si₃N₄ film, the use of N₂O-reoxidation significantly improves the quality of ON stacked film, resulting in ultrathin ON stacked film capacitors with excellent electrical properties and reliability     

Study of etch rate characteristics of SF6/He plasmas byresponse-surface methodology: effects of interelectrode spacing

The characteristics of SF₆/He plasmas which are used to etch Si₃N₄ have been examined with experimental design and modeled empirically by response-surface methodology using a Lam Research Autoetch 480 single-wafer system. The effects of variations of process gas flow rate (20-380 sccm), reactor pressure (300-900 mtorr). RF power (50-450 W at 13.56 MHz), and interelectrode spacing (8-25 mm) on the etch rates of LPCVD (low-pressure chemical vapor deposition) Si₃N₄, thermal SiO₂, and photoresist were examined at 22±2°C. Whereas the etch rate of photoresist increases with interelectrode spacing between 8 and 19 mm and then declines between 19 and 25 mm, the etch rate of Si₃N ₄ increases smoothly from 8 to 25 mm, while the etch rate of thermal SiO₂ shows no dependence on spacing between 8 and 25 mm. The etch rates of all three films decrease with increasing reactor pressure. Contour plots of the response surfaces for etch rate and etch uniformity of Si₃N₄ as a function of spacing and flow rate at constant RF power (250 W) display complex behavior at fixed reactor pressures. A satisfactory balance of etch rate and etch uniformity for Si₃N₄ is predicted at low reactor pressure (~300 mtorr), large electrode spacing (12-25 mm), and moderate process gas flow rates (20-250 sccm)     

Demonstration of Low-Leakage-Current Low-On-Resistance 600-V 5.5-A GaN/AlGaN HEMT

This letter demonstrates a high-voltage, high-current, and low-leakage-current GaN/AlGaN power HEMT with HfO₂ as the gate dielectric and passivation layer. The device is measured up to 600 V, and the maximum on-state drain current is higher than 5.5 A. Performance of small devices with HfO₂ and Si₃N₄ dielectrics is compared. The electric strength of gate dielectrics is measured for both HfO₂ and Si₃N₄. Devices with HfO₂ show better uniformity and lower leakage current than Si₃N₄ passivated devices. The 5.5-A HfO₂ devices demonstrate very low gate (41 nA/mm) and drain (430 nA/mm) leakage-current density and low on-resistance (6.2 Omegamiddotmm or 2.5 mOmegamiddotcm²).     

Highly reliable SiO2/Si3N4 stackeddielectric on rapid-thermal-nitrided rugged polysilicon for high-densityDRAM's

Experimental results are presented demonstrating that by using rapid thermal nitridation (RTN) of rugged poly-Si surface prior to Si ₃N₄ deposition, the quality and reliability of reoxidized Si₃N₄ dielectric (ON dielectric with an effective oxide thickness of about 35 Å) can be significantly improved over ON films on rugged poly-Si without RTN treatment. These improvements include significantly reduced defect-related dielectric breakdown, 10³ × increase in TDDB lifetime, lower leakage current, and suppressed electron-hole trapping and capacitance loss during stress     

The effect of surface passivation on the microwave characteristicsof undoped AlGaN/GaN HEMTs

Surface passivation of undoped AlGaN/CaN HEMT's reduces or eliminates the surface effects responsible for limiting both the RF current and breakdown voltages of the devices. Power measurements on a 2×125×0.5 μm AlGaN/GaN sapphire based HEMT demonstrate an increase in 4 GHz saturated output power from 1.0 W/mm [36% peak power-added efficiency (PAE)] to 2.0 W/mm (46% peak PAE) with 15 V applied to the drain in each case. Breakdown measurement data show a 25% average increase in breakdown voltage for 0.5 μm gate length HEMT's on the same wafer. Finally, 4 GHz power sweep data for a 2×75×0.4 μm AlGaN/GaN HEMT on sapphire processed using the Si₃N₄ passivation layer produced 4.0 W/mm saturated output power at 41% PAE (25 V drain bias). This result represents the highest reported microwave power density for undoped sapphire substrated AlGaN/GaN HEMT's     

氮化硅集成微腔光频梳器件关键制备技术(特邀)

微腔光频梳,又称微腔梳,是通过腔内四波混频过程产生的一种高相干宽谱的集成光源,有着优异的时频特性,可用于超精密分子光谱、相干通信、激光雷达、轻型化装备等测量应用,是基础科学、计量学及军事装备的重要工具,是一项颠覆性的技术。报道了一种集成氮化硅（Si₃N₄）微腔光频梳器件制备的关键技术,提出了一种方法平衡Si₃N₄的应力、厚度和化学计量之间的矛盾,以满足反常色散和减少双光子吸收的要求。利用这种改进的大马士革工艺微结构降低Si₃N₄厚膜的应力,减少应力缺陷对器件性能的影响,实现高品质Si₃N₄薄膜的可控制备。在微腔刻蚀工艺中,采用30 nm氧化铝牺牲层补偿掩模抗刻蚀能力,实现微环和波导侧壁粗糙度小于15 nm,满足了微腔高Q值的要求。经双光泵浦测量得到1 480~1 640 nm波段内的宽光谱高相干克尔光频梳。     

Quarter-micrometer low-noise pseudomorphic GaAs HEMTs withextremely low dependence of the noise figure on drain-sourcecurrent

Quarter-micrometer pseudomorphic (PM) AlGaAs-InGaAs-GaAs HEMTs with an In mole fraction of 21% have been successfully developed, fabricated, and characterized. The devices are realized in a commercial technology by using a multiple-gate-finger layout with air bridges for the interconnection of the source pads and a Si₃N₄ passivation. PM HEMTs with a gate width of 6×20 μm exhibit state-of-the-art noise figures of 0.65 and 0.82 dB with an associated gain of 14.5 and 11.5 dB at 12 and 18 GHz, respectively. The noise figure shows the lowest dependence on the drain-source current yet reported with ΔF_max<0.12 dB for a wide biasing range from 25% I_dss up to 150% I _dss at 12 GHz when I_dss=170-250 mA/mm     

Two silicon nitride technologies for post-SiO2 MOSFETgate dielectric

P-MOSFETs with 14 Å equivalent oxide thickness (EOT) were fabricated using both JVD Si₃N₄ and RTCVD Si₃ N₄/SiO_xN_y gate dielectric technologies. With gate length down to 80 nm, the two technologies produced very similar device performances, such as drive current and gate tunneling current. The low gate leakage current, good device characteristics and compatibility with conventional CMOS processing technology make both nitride gate dielectrics attractive candidates for post-SiO₂ scaling. The fact that two significantly different technologies produced identical results suggests that the process window should be quite large     

Novel cell transistor using retractedSi3N4-liner STI for the improvement of dataretention time in gigabit density DRAM and beyond

In this paper, we propose a novel cell transistor using retracted Si₃N₄-liner STI (shallow trench isolation) for the enhanced and reliable operation of 256-Mb dynamic random access memory (DRAM) in 0.15-μm technology. As the technology of DRAM has been developed into the sub-quarter-micron regime, the control of junction leakage current at the storage node is much more important due to the increased channel doping concentration. With the decreased parasitic electric field at the STI corner using the retracted Si₃N₄-liner, the inverse narrow width effect (INWE) was significantly reduced. The channel doping concentration, hence, was lowered without degrading the subthreshold leakage characteristics and the channel doping profile was optimized from the viewpoint of the electric field at local areas in the depletion region. In addition to the optimized channel doping profile resulted in a dramatic increase in data retention time and device yield for 256-Mb DRAM. The proposed cell transistor can be extended to future high-density DRAMs in 0.13-μm technology and beyond     

Responsivity and impact ionization coefficients ofSi1-xGex photodiodes

The spectral response and impact ionization coefficient ratio of Si_1-xGe_x have been determined. Measurements were made on p⁺-i-n⁺ diodes grown by solid/gas source molecular beam epitaxy. The diodes are characterized by reverse breakdown voltages of 4-12 V and dark currents of 20-170 pA/μm² . The long wavelength cut-off of the diodes increases from 1.2 μm to 1.6 μm as x increases from 0.08 to 1.0 with a maximum responsivity of 0.5 A/W in all the diodes tested. The ratio α/β varies from 3.3 to 0.3 in the same composition range, with α/β=1 at x≅0.45. These results have important implications in the use of this material system in various photodetection applications