An 8192-bit electrically alterable ROM employing a one-transistor cell with floating gate

Describes a fully decoded, TTL compatible, electrically alterable, 8-kbit MOS ROM using a two-level n-channel polysilicon gate process. The memory cell consists of a single transistor with stacked gate structure where the floating gate covers only one part of the channel and is extended to an erase overlap of the source diffusion region off the channel. Programming in typically 100 ms/word is achieved by injection of hot electrons from the short channel (3.5 /spl mu/m) into the floating gate. Electrical block erasure is performed by Fowler-Nordheim emission of electrons from the floating gate. To avoid excessive avalanche breakdown currents during erasure 40 nm-50 nm oxides at the erase overlap and a voltage ramp are used. The memory operates with standard voltages (/spl plusmn/5 V, +12 V), during read, program and erase operation, a single pulsed high voltage (+26 V) for programming, and an erase voltage ramp of +35 V maximum. Typical access time is 250 ns.     

MONOS memory in sequential laterally solidified low-temperature poly-Si TFTs

A metal-oxide-nitride-oxide-polysilicon (MONOS) memory device fabricated by sequential lateral solidified (SLS) low-temperature polycrystalline silicon (poly-Si) technology on a glass substrate was investigated. The Si protrusions at grain boundaries (GBs) as a result of the SLS process can be well controlled and located along the width direction of the transistor. Protrusions at the GBs are utilized as emitting source to achieve a MONOS memory device with low operation voltage (/spl les/ 20 V), fast program/erase time, and wide V/sub th/ window by field-enhanced channel hot electron injection for programming and field-enhanced band-to-band tunneling-induced hot hole injection for erase. This is the first study to demonstrate a nonvolatile memory device in low-temperature poly-Si thin-film transistor (LTPS TFT) technology, which can be integrated with TFT-liquid crystal display, to reduce power consumption for mobile applications.     

Memory characteristics of MOSFETs with densely stacked silicon nanocrystal Layers in the gate oxide synthesized by low-energy ion beam

Densely stacked silicon nanocrystal layers embedded in the gate oxide of MOSFETs are synthesized with Si ion implantation into an SiO/sub 2/ layer at an implantation energy of 2 keV. In this letter, the memory characteristics of MOSFETs with 7-nm tunnel oxide and 20-nm control oxide at various temperatures have been investigated. A threshold voltage window of /spl sim/ 0.5 V is achieved under write/erase (W/E) voltages of +12 V/-12 V for 1 ms. The devices exhibit good endurance up to 10/sup 5/ W/E cycles even at a high operation temperature of 150/spl deg/C. They also have good retention characteristics with an extrapolated ten-year memory window of /spl sim/ 0.3 V at 100/spl deg/C.     

Low Voltage Flash Memory Cells Using SiGe Quantum Dots for Enhancing F-N Tunneling

提出了一种用于半导体闪速存储器单元的新的Si/SiGe量子点/隧穿氧化层/多晶硅栅多层结构,该结构可以实现增强F-N隧穿的编程和擦除机制.模拟结果表明该结构具有高速和高可靠性的优点.测试结果表明该结构的工作电压比传统NAND结构的存储器单元降低了4V.采用该结构能够实现高速、低功耗和高可靠性的半导体闪速存储器.     

基于SiGe量子点实现增强F-N隧穿的低压闪速存储器

提出了一种用于半导体闪速存储器单元的新的Si/SiGe量子点/隧穿氧化层/多晶硅栅多层结构,该结构可以实现增强F-N隧穿的编程和擦除机制.模拟结果表明该结构具有高速和高可靠性的优点.测试结果表明该结构的工作电压比传统NAND结构的存储器单元降低了4V.采用该结构能够实现高速、低功耗和高可靠性的半导体闪速存储器.     

A novel program-erasable high-/spl kappa/ AlN-Si MIS capacitor

We demonstrate a programmable-erasable MIS capacitor with a single layer high-/spl kappa/ AlN dielectric on Si having a high capacitance density of /spl sim/5 fF//spl mu/m/sup 2/. It has low program and erase voltages of +4 and -4 V, respectively. Such an erase function is not available in other single layer Al/sub 2/O/sub 3/, AlON, or other known high-/spl kappa/ dielectric capacitors, where the threshold voltage (V/sub th/) shifts continuously with voltage. This device exhibits good data retention with a V/sub th/ change of only 0.06 V after 10 000 s.     

Positive oxide charge-enhanced read disturb in a localized trapping storage flash memory cell

Read disturb-induced erase-state threshold voltage instability in a localized trapping storage Flash memory cell with a poly-silicon-oxide-nitride-oxide-silicon (SONOS) structure is investigated and reported. Our results show that positive trapped charge in bottom oxide generated during program/erase (P/E) cycles play a major role. Both gate voltage and drain voltage will accelerate the threshold voltage (V/sub t/) drift. Hot-carrier caused disturb effect is more severe in a shorter gate length device at low temperature. A model of positive charge-assisted electron tunneling into a trapping nitride is proposed. Influence of channel doping on the V/sub t/ drift is studied. As the cell is in an "unbiased" storage mode, tunnel detrapping of positive oxide charges is responsible for the threshold voltage shift, which is insensitive to temperature.     

新型嵌入式BeNOR结构Flash存贮器

提出了一种能根据嵌入式应用系统容量的不同而灵活选择字节擦除和块擦除两种不同擦除模式的BeNOR阵列结构,该结构采用沟道热电子注入进行"写"操作,采用分离电压法负栅压源极F-N隧道效应进行擦除.对分离电压法负栅压源极F-N隧道效应擦除的研究表明,采用源极电压为5V,栅极电压为-10V的擦除条件,不仅能很好地控制擦除后的阈值电压,而且当字线宽度小于等于64时,源极电压导致的串扰效应能得到很好的抑制.研究表明该结构具有编程速度高、读取速度高、可靠性高及系统应用灵活的特点,非常适宜于在1M位以下的嵌入式系统中应用.     

High-voltage normally off GaN MOSFETs on sapphire substrates

Gallium nitride self-aligned MOSFETs were fabricated using low-pressure chemical vapor-deposited silicon dioxide as the gate dielectric and polysilicon as the gate material. Silicon was implanted into an unintentionally doped GaN layer using the polysilicon gate to define the source and drain regions, with implant activation at 1100/spl deg/C for 5 min in nitrogen. The GaN MOSFETs have a low gate leakage current of less than 50 pA for circular devices with W/L=800/128 /spl mu/m. Devices are normally off with a threshold voltage of +2.7 V and a field-effect mobility of 45 cm/sup 2//Vs at room temperature. The minimum on-resistance measured is 1.9 m/spl Omega//spl middot/cm/sup 2/ with a gate voltage of 34 V (W/L=800/2 /spl mu/m). High-voltage lateral devices had a breakdown voltage of 700 V with gate-drain spacing of 9 /spl mu/m (80 V//spl mu/m), showing the feasibility of self-aligned GaN MOSFETs for high-voltage integrated circuits.     

Impact of metal work function on memory properties of charge-trap flash memory devices using fowler-nordheim P/E mode

This letter reports the impact of metal work function (/spl Phi//sub M/) on memory properties of charge-trap-Flash memory devices using Fowler-Nordheim program/erase mode. For eliminating electron back tunneling and hole back tunneling through the blocking oxide during an program/erase operation, a gate with /spl Phi//sub M/ of 5.1-5.7 eV on an Al/sub 2/O/sub 3/-SiN-SiO/sub 2/ (ANO) stack is necessary. Compared to a thickness optimized n/sup +/ poly-Si/ONO stack, a high-work-function gate on an ANO stack shows dramatic improvements in retention versus minimum erase state.     

New nonvolatile memory with charge-trapping sidewall

This letter reports on the development of a new nonvolatile memory with charge-trapping sidewalls using sub-0.1-/spl mu/m MOSFET technology. This memory has silicon nitride (SiN) sidewalls at both sides of the gate to store the charge. We have found that optimization of the p-n junction edge with the sidewall enables writing, reading, and erasing a 2-bit charge independently. The Vth window, which is the difference in the threshold voltage between forward and reverse read, was about 0.8 V with a gate length of 0.4 /spl mu/m. In addition, it is scalable to 40 nm of the gate length. This device is attractive not only from the prospects of future size reduction, but also its compatibility with CMOS process.     

MAS-ROM-electrically reprogrammable ROM with decoder

The electrical characteristics of an MAS-ROM with on-the-chip X-Y matrix decoding and its reliabilities are evaluated. The MOS-ROM makes use of the so-called charge-storage phenomena in the gate insulator film and provides an electrical reprogrammable and nonvolatile integrated-circuit memory device in which one memory cell is composed only of an N-channel enhancement-type MAS transistor. The threshold voltage of the transistor is selectively increased by electron injection from the channel and decreased by the application of high negative voltage to the gate. The reliability test shows that the long-term decay has a logarithmic dependence on time with a slope of 0.7 V per decade of storage time under a gate voltage of +10 V at 150/spl deg/C.     

Room-temperature continuous-wave operation of GaInNAsSb laser diodes at 1.55 /spl mu/m

The first 1.55 /spl mu/m room-temperature continuous-wave (CW) operation of GaAs-based laser diodes utilising GaInNAsSb/GaNAs double quantum well active regions grown by molecular beam epitaxy is reported. In electrically-pumped CW operation the narrow ridge waveguide devices have a room temperature lasing wavelength of 1550 nm near threshold, increasing to 1553 nm at thermal rollover. The CW threshold current was 132 mA for a 3/spl times/589 /spl mu/m device, with a characteristic temperature of 83 K, measured in pulsed mode between 20 and 70/spl deg/C.     

A novel PHINES flash memory cell with low power program/erase, small pitch, two-bits-per-cell for data storage applications

A novel programming by hot-hole injection nitride electron storage (PHINES) Flash memory technology is developed. The memory bit size of 0.046 /spl mu/m/sup 2/ is fabricated based on 0.13-/spl mu/m technology. PHINES cell uses a nitride trapping storage cell structure. Fowler-Nordheim (FN) injection is performed to raise V/sub t/ in erase while programming is done by lowering a local V/sub t/ through band-to-band tunneling-induced hot hole (BTBT HH) injection. Two-bits-per-cell feasibility, low-power and high-speed program/erase, good endurance and data retentivity make it a promising candidate for Flash EEPROM technology in gigabit era applications.     

Comparison of MONOS Memory Device Integrity When Using $hbox{Hf}_{1 - x - y}hbox{N}_{x}hbox{O}_{y}$ Trapping Layers With Different N Compositions

We have studied the nitrogen composition dependence of the characteristics of Hf_1-x-yN_xO_y/SiO₂/Si MONOS memory devices. By increasing the N composition in the Hf_1-x-yN_xO_y trapping layer, both the memory window and high-temperature retention improved. The Hf_0.3N_0.2O_0.5 MONOS device displayed good characteristics in terms of its plusmn9-V program/erase (P/E) voltage, 100-mus P/E speed, large initial 2.8-V memory window, and a ten-year extrapolated retention of 1.8 V at 85degC or 1.5 V at 125degC.     

High-performance enhancement-mode AlGaN/GaN HEMTs using fluoride-based plasma treatment

We report a novel approach in fabricating high-performance enhancement mode (E-mode) AlGaN/GaN HEMTs. The fabrication technique is based on fluoride-based plasma treatment of the gate region in AlGaN/GaN HEMTs and post-gate rapid thermal annealing with an annealing temperature lower than 500/spl deg/C. Starting with a conventional depletion-mode HEMT sample, we found that fluoride-based plasma treatment can effectively shift the threshold voltage from -4.0 to 0.9 V. Most importantly, a zero transconductance (g/sub m/) was obtained at V/sub gs/=0 V, demonstrating for the first time true E-mode operation in an AlGaN/GaN HEMT. At V/sub gs/=0 V, the off-state drain leakage current is 28 /spl mu/A/mm at a drain-source bias of 6 V. The fabricated E-mode AlGaN/GaN HEMTs with 1 /spl mu/m-long gate exhibit a maximum drain current density of 310 mA/mm, a peak g/sub m/ of 148 mS/mm, a current gain cutoff frequency f/sub T/ of 10.1 GHz and a maximum oscillation frequency f/sub max/ of 34.3 GHz.     

A single-sided PHINES SONOS memory featuring high-speed and low-power applications

A single-sided PHINES SONOS memory with hot-hole injection in program operation and Fowler-Nordheim (FN) tunneling in erase operation has been demonstrated for high program speed and low power applications. High programming speed (/spl Delta/V/sub t//program time) of 5 V/20 /spl mu/s, low power consumption of P/E, high endurance of 10 K, good retention, and scaling capability can be demonstrated.     

A nonvolatile charge-addressed memory (NOVCAM) cell

A nonvolatile charge-addressed memory (NOVCAM) cell is described in a 64-bit shift register configuration. The charge address is performed by a charge-coupled device (CCD) shift register and the information is stored in metal-nitride-oxide-silicon (MNOS) nonvolatile sites located in parallel with the CCD shift register. The tunneling electric field strength across the thin-oxide MNOS structure is controlled by the magnitude of the charge transferred from the CCD register. The write, erase, and read modes of operation are discussed with typical /spl plusmn/20 V 10 /spl mu/s write/erase, and 2 V 2 /spl mu/s read conditions. Readout is accomplished by parallel stabilized charge injection from a diffused p/n junction to minimize access time to the first bit.     

A novel MONOS nonvolatile memory device ensuring 10-year dataretention after 107 erase/write cycles

A highly reliable nonvolatile memory device suitable for high-density electrically erasable and programmable read only memories (EEPROMs) is described. A metal-oxide-nitride-oxide-semiconductor (MONOS) structure whose top oxide is fabricated by chemical vapor deposition (CVD) on the nitride is proposed. This CVD oxide is densified by pyrogenic annealing and has stoichiometric SiO₂ characteristics. Its potential barrier, which prevents stored charges from decaying through the top oxide to the gate, thus becomes sharper than that of the thermally grown top oxide used in the conventional MONOS structure. For comparison between the proposed MONOS, conventional MONOS, and MNOS structures, three devices were fabricated on the same process line. The 16.7-nm nitride thickness in combination with a top oxide thickness of 4.0 nm results in a gate capacitance equivalent to that of the conventional NMOS structure with a 23.5-nm nitride thickness. Moreover, an asymmetric erase/write programming voltage has been adapted to the MONOS device operation by considering both erased-state degradation and written-state retention. At 85 °C, the proposed MONOS device has 10⁷-cycle endurance with 10-year data retention     

A very high precision 500-nA CMOS floating-gate analog voltage reference

A floating gate with stored charge technique has been used to implement a precision voltage reference achieving a temperature coefficient (TC) <1 ppm//spl deg/C in CMOS technology. A Fowler-Nordheim tunnel device used as a switch and a poly-poly capacitor form the basis in this reference. Differential dual floating gate architecture helps in achieving extremely low temperature coefficients, and improving power supply rejection. The reference is factory programmed to any value without any trim circuits to within 200 /spl mu/V of its specified value. The floating-gate analog voltage reference (FGAREF) shows a long-term drift of less than 10 ppm//spl radic/1000 h. This circuit is ideal for portable and handheld applications with a total current of only 500 nA. This is done by biasing the buffer amplifier in the subthreshold region of operation. It is fabricated using a 25-V 1.5-/spl mu/m E/sup 2/PROM CMOS technology.