High-Density and Low-Leakage-Current MIM Capacitor Using Stacked $hbox{TiO}_{2}/hbox{ZrO}_{2}$ Insulators

We have fabricated high-$kappa hbox{Ni}/hbox{TiO}_{2}/hbox{ZrO}_{2}/ hbox{TiN}$ metal–insulator–metal (MIM) capacitors. A low leakage current of $hbox{8} times hbox{10}^{-8} hbox{A/cm}^{2}$ at 125 $^{circ}hbox{C}$ was obtained with a high 38- $hbox{fF}/muhbox{m}^{2}$ capacitance density and better than the $hbox{ZrO}_{2}$ MIM capacitors. The excellent device performance is due to the lower electric field in 9.5-nm-thick $hbox{TiO}_{2}/ hbox{ZrO}_{2}$ devices to decrease the leakage current and to a higher $kappa$ value of 58 for $ hbox{TiO}_{2}$ as compared with that of $hbox{ZrO}_{2}$ to preserve the high capacitance density.      

Improved Stress Reliability of Analog Metal–Insulator–Metal Capacitors Using $hbox{TiO}_{2}/hbox{ZrO}_{2}$ Dielectrics

We have studied the stress reliability of high-$kappa$ $hbox{Ni/TiO}_{2}/hbox{ZrO}_{2}/hbox{TiN}$ metal–insulator–metal capacitors under constant-voltage stress. The increasing $hbox{TiO}_{2}$ thickness on $hbox{ZrO}_{2}$ improves the 125-$^{circ}hbox{C}$ leakage current, capacitance variation $(Delta C/C)$, and long-term reliability. For a high density of 26 $hbox{fF}/mu hbox{m}^{2}$ , good extrapolated ten-year reliability of small $Delta C/ break C sim hbox{0.71}%$ is obtained for the $ hbox{Ni/10-nm-}hbox{TiO}_{2}/hbox{6.5-nm-} hbox{ZrO}_{2}/break hbox{TiN}$ device at 2.5-V operation.      

$hbox{TiN/ZrO}_{2}$/Ti/Al Metal–Insulator–Metal Capacitors With Subnanometer CET Using ALD-Deposited $hbox{ZrO}_{2}$ for DRAM Applications

We provide the first report of the structural and electrical properties of $hbox{TiN/ZrO}_{2}$/Ti/Al metal–insulator–metal capacitor structures, where the $hbox{ZrO}_{2}$ thin film (7–8 nm) is deposited by ALD using the new zirconium precursor ZrD-04, also known as Bis(methylcyclopentadienyl) methoxymethyl. Measured capacitance–voltage ($C$– $V$) and current–voltage ( $I$–$V$) characteristics are reported for premetallization rapid thermal annealing (RTP) in $hbox{N}_{2}$ for 60 s at 400 $^{circ}hbox{C}$, 500 $^{circ}hbox{C}$, or 600 $^{ circ}hbox{C}$. For the RTP at 400 $^{circ}hbox{C}$ , we find very low leakage current densities on the order of nanoamperes per square centimeter at a gate voltage of 1 V and low capacitance equivalent thickness values of $sim$ 0.9 nm at a gate voltage of 0 V. The dielectric constant of $ hbox{ZrO}_{2}$ is 31 $pm$ 2 after RTP treatment at 400 $^{circ}hbox{C}$.      

Second-Bit-Effect-Free Multibit-Cell Flash Memory Using $hbox{Si}_{3} hbox{N}_{4}/hbox{ZrO}_{2}$ Split Charge Trapping Layer

In this paper, a $hbox{Si}_{3}hbox{N}_{4}/hbox{ZrO}_{2}$ split charge trapping layer (SCTL) is proposed for multibit-cell Flash memory. The complementary potential wells of $hbox{Si}_{3}hbox{N}_{4}/hbox{ZrO}_{2}$ storage nodes enable independent node control when the Fowler–Nordheim (F–N) method is applied for programming/erasing (P/E). Experiment and simulation results suggest that the 2-bit (2-b) charge storage is accomplished by physical data node separation for the SCTL rather than charge injection control. The well-confined charge storages suppress the second-bit effect, enabling excellent 2-b data clearance for short-channel SCTL devices. It was found that the remaining memory windows after $hbox{10}^{5} hbox{s}$ decrease, dependent on the difference of the trap properties between $ hbox{Si}_{3}hbox{N}_{4}$ and $hbox{ZrO}_{2}$.      

Low-Voltage Organic Field-Effect Transistor With PMMA/$ hbox{ZrO}_{2}$ Bilayer Dielectric

This paper reports on the application of a bilayer polymethylmethacrylate (PMMA)/ $hbox{ZrO}_{2}$ dielectric in copper phthalocyanine (CuPc) organic field-effect transistors (OFETs). By depositing a PMMA layer on $hbox{ZrO}_{2}$, the leakage of the dielectric is reduced by one order of magnitude compared to single-layer $hbox{ZrO}_{2}$. A high-quality interface is obtained between the organic semiconductor and the combined insulators. By integrating the advantages of polymer and high- $k$ dielectrics, the device achieves both high mobility and low threshold voltage. The typical field-effect mobility, threshold voltage, on/off current ratio, and subthreshold slope of OFETs with bilayer dielectric are $hbox{5.6}timeshbox{10}^{-2} hbox{cm}^{2}/hbox{V} cdot hbox{s}$, 0.8 V, $hbox{1.2} times hbox{10}^{3}$, and 2.1 V/dec, respectively. By using the bilayer dielectrics, the hysteresis observed in the devices with single-layer $hbox{ZrO}_{2}$ is no longer present.      

Positive Bias Temperature Instability (PBTI) Characteristics of Contact-Etch-Stop-Layer-Induced Local-Tensile-Strained $hbox{HfO}_{2}$ nMOSFET

The positive bias temperature instability (PBTI) characteristics of contact-etch-stop-layer (CESL)-strained $hbox{HfO}_{2}$ nMOSFET are thoroughly investigated. For the first time, the effects of CESL on an $hbox{HfO}_{2}$ dielectric are investigated for PBTI characteristics. A roughly 50% reduction of $V_{rm TH}$ shift can be achieved for the 300-nm CESL $hbox{HfO}_{2}$ nMOSFET after 1000-s PBTI stressing without obvious $ hbox{HfO}_{2}/hbox{Si}$ interface degradation, as demonstrated by the negligible charge pumping current increase ($≪$ 4%). In addition, the $hbox{HfO}_{2}$ film of CESL devices has a deeper trapping level (0.83 eV), indicating that most of the shallow traps (0.75 eV) in as-deposited $ hbox{HfO}_{2}$ film can be eliminated for CESL devices.      

A Comparative NBTI Study of $hbox{HfO}_{2}$, $hbox{HfSiO}_{x}$, and SiON p-MOSFETs Using UF-OTF $I_{rm DLIN}$ Technique

The time, temperature, and oxide-field dependence of negative-bias temperature instability is studied in $hbox{HfO}_{2}/hbox{TiN}$, $ hbox{HfSiO}_{x}/hbox{TiN}$, and SiON/poly-Si p-MOSFETs using ultrafast on-the-fly $I_{rm DLIN}$ technique capable of providing measured degradation from very short (approximately microseconds) to long stress time. Similar to rapid thermal nitrided oxide (RTNO) SiON, $hbox{HfO}_{2}$ devices show very high temperature-independent degradation at short (submilliseconds) stress time, not observed for plasma nitrided oxide (PNO) SiON and $hbox{HfSiO}_{x}$ devices. $hbox{HfSiO}_{x}$ shows lower overall degradation, higher long-time power-law exponent, field acceleration, and temperature activation as compared to $hbox{HfO}_{2}$, which are similar to the differences between PNO and RTNO SiON devices, respectively. The difference between $ hbox{HfSiO}_{x}$ and $hbox{HfO}_{2}$ can be attributed to differences in N density in the $hbox{SiO}_{2}$ IL of these devices.      

Nonvolatile Memory With TiN Nanocrystals Three-Dimensionally Embedded in $hbox{Si}_{3}hbox{N}_{4}$ Formed by Spinodal Phase Segregation

In this letter, TiN nanocrystals three-dimensionally embedded in the $ hbox{Si}_{3}hbox{N}_{4}$ formed by spinodal phase segregation was investigated as the discrete charge-trapping layer in a metal–oxide–nitride–oxide–silicon structure for nonvolatile-memory applications. TiN-nanocrystal formation was verified by X-ray diffraction analysis while the 3-D distribution of nanocrystals in the $hbox{Si}_{3}hbox{N}_{4}$ film was confirmed by transmission electron microscopy with the average size of 5.1 nm and a density of $hbox{9.8} timesbreak hbox{10}^{11} hbox{cm}^{-2}$. The promising memory performance was evidenced by the large memory window of 1.81 V with $pm$4-V program/erase voltage, the high operation speed of 1.52-V threshold-voltage shift by programming at $+$4 V for 10 ms, the negligible memory-window degradation up to $hbox{10}^{5}$ operation cycles, and 11% charge loss after ten-year operation. Most importantly, the charge-storage structure can be formed by a cosputtering approach which is simple and fully compatible with existent ultralarge scale integration technology.      

$hbox{HfO}_{x}$ Bipolar Resistive Memory With Robust Endurance Using AlCu as Buffer Electrode

A novel method of fabricating $hbox{HfO}_{x}$-based resistive memory device with excellent nonvolatile characteristics is proposed. By using a thin AlCu layer as the reactive buffer layer into the anodic side of a capacitor-like memory cell, excellent memory performances, which include reliable programming/erasing endurance $(≫ hbox{10}^{5} hbox{cycles})$, robust data retention at high temperature, and fast operation speed ( $≪$ 50 ns), have been demonstrated. The resistive memory based on AlCu/$hbox{HfO}_{x}$ stacked layer in this letter shows promising application in the next generation of nonvolatile memory.      

Resistive Switching Properties of $hbox{Au}/ hbox{ZrO}_{2}/hbox{Ag}$ Structure for Low-Voltage Nonvolatile Memory Applications

The reliable resistive switching properties of $hbox{Au}/hbox{ZrO}_{2}/ hbox{Ag}$ structure fabricated with full room temperature process are demonstrated in this letter. The tested devices show low operation voltages ($≪hbox{1}$ V), high resistance ratio (about $hbox{10}^{4}$), fast switching speed (50 ns), and reliable data retention (ten years extrapolation at both RT and 85 $^{circ}hbox{C}$). Moreover, the benefits of high yield and multilevel storage possibility make them promising in the next generation nonvolatile memory applications.      

1580-V–40-$hbox{m}Omegacdot hbox{cm}^{2}$ Double-RESURF MOSFETs on 4H-SiC $(hbox{000}bar{hbox{1}})$

Double-reduced-surface-field (RESURF) MOSFETs with $hbox{N}_{2}hbox{O}$ -grown oxides have been fabricated on the 4H-SiC $(hbox{000} bar{hbox{1}})$ face. The double-RESURF structure is effective in reducing the drift resistance, as well as in increasing the breakdown voltage. In addition, by utilizing the 4H-SiC $(hbox{000}bar{hbox{1}})$ face, the channel mobility can be increased to over 30 $hbox{cm}^{2}/hbox{V}cdothbox{s}$, and hence, the channel resistance is decreased. As a result, the fabricated MOSFETs on 4H-SiC $( hbox{000}bar{hbox{1}})$ have demonstrated a high breakdown voltage $(V_{B})$ of 1580 V and a low on-resistance $(R_{rm ON})$ of 40 $hbox{m}Omega cdothbox{cm}^{2}$. The figure-of-merit $(V_{B}^{2}/R_{rm ON})$ of the fabricated device has reached 62 $hbox{MW/cm}^{2}$, which is the highest value among any lateral MOSFETs and is more than ten times higher than the “Si limit.”      

Performance Improvement of N-Type $hbox{TiO}_{x}$ Active-Channel TFTs Grown by Low-Temperature Plasma-Enhanced ALD

We report on performance improvement of $n$-type oxide–semiconductor thin-film transistors (TFTs) based on $hbox{TiO}_{x}$ active channels grown at 250 $^{circ}hbox{C}$ by plasma-enhanced atomic layer deposition. TFTs with as-grown $hbox{TiO}_{x}$ films exhibited the saturation mobility $(mu_{rm sat})$ as high as 3.2 $hbox{cm}^{2}/hbox{V}cdothbox{s}$ but suffered from the low on–off ratio $(I_{rm ON}/I_{rm OFF})$ of $hbox{2.0} times hbox{10}^{2}$. $hbox{N}_{2}hbox{O}$ plasma treatment was then attempted to improve $I_{rm ON}/I_{rm OFF}$. Upon treatment, the $hbox{TiO}_{x}$ TFTs exhibited $I_{rm ON}/I_{rm OFF}$ of $hbox{4.7} times hbox{10}^{5}$ and $mu_{rm sat}$ of 1.64 $hbox{cm}^{2}/hbox{V}cdothbox{s}$, showing a much improved performance balance and, thus, demonstrating their potentials for a wide variety of applications such as backplane technology in active-matrix displays and radio-frequency identification tags.      

Electrical Properties of Amorphous $hbox{Bi}_{5} hbox{Nb}_{3}hbox{O}_{15}$ Thin Film for RF MIM Capacitors

Amorphous $hbox{Bi}_{5}hbox{Nb}_{3}hbox{O}_{15}(hbox{B}_{5} hbox{N}_{3})$ film grown at 300 $^{circ}hbox{C}$ showed a high-$k$ value of 71 at 100 kHz, and similar $k$ value was observed at 0.5–5.0 GHz. The 80-nm-thick film exhibited a high capacitance density of 7.8 fF/$muhbox{m}^{2}$ and a low dissipation factor of 0.95% at 100 kHz with a low leakage-current density of 1.23 nA/ $hbox{cm}^{2}$ at 1 V. The quadratic and linear voltage coefficient of capacitances of the $hbox{B}_{5}hbox{N}_{3}$ film were 438 ppm/$hbox{V}^{2}$ and 456 ppm/V, respectively, with a low temperature coefficient of capacitance of 309 ppm/$^{circ}hbox{C}$ at 100 kHz. These results confirmed the potential of the amorphous $hbox{B}_{5}hbox{N}_{3}$ film as a good candidate material for a high-performance metal–insulator–metal capacitors.      

Fabrication and Properties of $hbox{Pt}/hbox{Bi}_{3.15}hbox{Nd}_{0.85} hbox{Ti}_{3}hbox{O}_{12}/breakhbox{HfO}_{2}/hbox{Si}$ Structure for Ferroelectric DRAM (FEDRAM) FET

Metal–ferroelectric–insulator–semiconductor (MFIS) capacitors with 400-nm-thick $hbox{Bi}_{3.15}hbox{Nd}_{0.85}hbox{Ti}_{3}hbox{O}_{12}$ (BNdT) ferroelectric film and 4-nm-thick hafnium oxide $(hbox{HfO}_{2})$ layer on silicon substrate have been fabricated and characterized. It is demonstrated that the $hbox{Pt}/hbox{Bi}_{3.15}hbox{Nd}_{0.85}hbox{Ti}_{3}hbox{O}_{12}/ hbox{HfO}_{2}/hbox{Si}$ structure exhibits a large memory window of around 1.12 V at an operation voltage of 3.5 V. Moreover, the MFIS memory structure suffers only 10% degradation in the memory window after $hbox{10}^{10}$ switching cycles. The retention time is 100 s, which is enough for ferroelectric DRAM field-effect-transistor application. The excellent performance is attributed to the formation of well-crystallized BNdT perovskite thin film on top of the $ hbox{HfO}_{2}$ buffer layer, which serves as a good seed layer for BNdT crystallization, making the proposed $hbox{Pt}/hbox{Bi}_{3.15}hbox{Nd}_{0.85}hbox{Ti}_{3}hbox{O}_{12}/ hbox{HfO}_{2}/hbox{Si}$ suitable for high-performance ferroelectric memories.      

Resistive-Switching Characteristics of $hbox{Al}/ hbox{Pr}_{0.7}hbox{Ca}_{0.3}hbox{MnO}_{3}$ for Nonvolatile Memory Applications

A systematic study on the switching mechanism of an $hbox{Al}/ hbox{Pr}_{0.7}hbox{Ca}_{0.3}hbox{MnO}_{3}$ (PCMO) device was performed. A polycrystalline PCMO film was deposited using a conventional sputtering method. A thin Al layer was introduced to induce a reaction with the PCMO, forming aluminum oxide $(hbox{AlO}_{x})$. Transmission electron microscopy analysis of the interface between Al and PCMO showed that resistive switching was governed by the formation and dissolution of $hbox{AlO}_{x}$. Some basic memory characteristics, such as good cycle endurance and data retention of up to $hbox{10}^{4}$ s at 125 $^{circ}hbox{C}$, were also obtained. It also showed excellent switching uniformity and high device yield.      

Lattice-Mismatched $hbox{In}_{0.4}hbox{Ga}_{0.6} hbox{As}$ Source/Drain Stressors With In Situ Doping for Strained $hbox{In}_{0.53}hbox{Ga}_{0.47}hbox{As}$ Channel n-MOSFETs

We report the first demonstration of a strained $hbox{In}_{0.53} hbox{Ga}_{0.47}hbox{As}$ channel n-MOSFET featuring in situ doped $hbox{In}_{0.4}hbox{Ga}_{0.6}hbox{As}$ source/drain (S/D) regions. The in situ silicondoped $hbox{In}_{0.4}hbox{Ga}_{0.6}hbox{As}$ S/D was formed by a recess etch and a selective epitaxy of $hbox{In}_{0.4}hbox{Ga}_{0.6}hbox{As}$ in the S/D by metal–organic chemical vapor deposition. A lattice mismatch of $sim$0.9% between $ hbox{In}_{0.53}hbox{Ga}_{0.47}hbox{As}$ and $hbox{In}_{0.4} hbox{Ga}_{0.6}hbox{As}$ S/D gives rise to lateral tensile strain and vertical compressive strain in the $hbox{In}_{0.53}hbox{Ga}_{0.47}hbox{As}$ channel region. In addition, the in situ Si-doping process increases the carrier concentration in the S/D regions for series-resistance reduction. Significant drive-current improvement over the control n-MOSFET with Si-implanted $hbox{In}_{0.53}hbox{Ga}_{0.47}hbox{As}$ S/D regions was achieved. This is attributed to both the strain-induced band-structure modification in the channel that reduces the effective electron mass along the transport direction and the reduction in the S/D series resistance.      

Impacts of $hbox{N}_{2}$ and $hbox{NH}_{3}$ Plasma Surface Treatments on High-Performance LTPS-TFT With High-$kappa$ Gate Dielectric

Low-temperature polycrystalline-silicon thin-film transistors (LTPS-TFTs) with high- $kappa$ gate dielectrics and plasma surface treatments are demonstrated for the first time. Significant field-effect mobility $mu_{rm FE}$ improvements of $sim$86.0% and 112.5% are observed for LTPS-TFTs with $hbox{HfO}_{2}$ gate dielectric after $hbox{N}_{2}$ and $ hbox{NH}_{3}$ plasma surface treatments, respectively. In addition, the $hbox{N}_{2}$ and $ hbox{NH}_{3}$ plasma surface treatments can also reduce surface roughness scattering to enhance the field-effect mobility $mu_{rm FE}$ at high gate bias voltage $V_{G}$, resulting in 217.0% and 219.6% improvements in driving current, respectively. As a result, high-performance LTPS-TFT with low threshold voltage $V_{rm TH} sim hbox{0.33} hbox{V}$, excellent subthreshold swing S.S. $sim$0.156 V/decade, and high field-effect mobility $mu_{rm FE} sim hbox{62.02} hbox{cm}^{2}/hbox{V} cdot hbox{s}$ would be suitable for the application of system-on-panel.      

Comparative Study of the Low-Frequency-Noise Behaviors in a-IGZO Thin-Film Transistors With $hbox{Al}_{2}hbox{O}_{3}$ and $hbox{Al}_{2}hbox{O}_{3}/hbox{SiN}_{x}$ Gate Dielectrics

A comparative study is made of the low-frequency noise (LFN) in amorphous indium–gallium–zinc oxide (a-IGZO) thin-film transistors (TFTs) with $hbox{Al}_{2}hbox{O}_{3}$ and $hbox{Al}_{2}hbox{O}_{3}/hbox{SiN}_{x}$ gate dielectrics. The LFN is proportional to $hbox{1}/f^{gamma}$, with $gamma sim hbox{1}$ for both devices, but the normalized noise for the $hbox{Al}_{2}hbox{O}_{3}/hbox{SiN}_{x}$ device is two to three orders of magnitude lower than that for the $hbox{Al}_{2} hbox{O}_{3}$ device. The mobility fluctuation is the dominant LFN mechanism in both devices, but the noise from the source/drain contacts becomes comparable to the intrinsic channel noise as the gate overdrive voltage increases in $hbox{Al}_{2}hbox{O}_{3}/hbox{SiN}_{x}$ devices. The $hbox{SiN}_{x}$ interfacial layer is considered to be very effective in reducing LFN by suppressing the remote phonon scattering from the $hbox{Al}_{2}hbox{O}_{3}$ dielectric. Hooge's parameter is extracted to $sim !!hbox{6.0} times hbox{10}^{-3}$ in $hbox{Al}_{2}hbox{O}_{3}/hbox{SiN}_{x}$ devices.      

Effect of Oxygen Pressure on the Electrical Properties of $hbox{Bi}_{5} hbox{Nb}_{3}hbox{O}_{15}$ Films Grown by RF Magnetron Sputtering

$hbox{Bi}_{5}hbox{Nb}_{3}hbox{O}_{15} (hbox{B}_{5}hbox{N}_{3})$ films grown under a low oxygen partial pressure (OP) of 1.7 mtorr showed a high leakage current density of 0.1 $hbox{A/cm}^{2}$ at 1.0 MV/cm. However, the leakage current density decreased with increasing OP to a minimum of $hbox{5.8} times hbox{10}^{-9} hbox{A/cm}^{2}$ for the film grown under 5.1 mtorr due to the decreased number of oxygen vacancies. This film also showed an improved breakdown field of 2.2 MV/cm and a large capacitance density of 24.9 $hbox{fF}/muhbox{m}^{2}$. The electrical properties of the film, however, deteriorated with a further increase in OP, which is probably due to the formation of oxygen interstitial ions. Therefore, superior electrical properties for the $ hbox{B}_{5}hbox{N}_{3}$ film can be obtained by careful control of OP.      

Electrical Properties of $hbox{Bi}_{5}hbox{Nb}_{3} hbox{O}_{15}$ Thin Film Grown on $hbox{TiN}/hbox{SiO}_{2}/ hbox{Si}$ at Room Temperature for Metal–Insulator–Metal Capacitors

Buckling was observed in $hbox{Bi}_{5}hbox{Nb}_{3}hbox{O}_{15}$ (BiNbO) films grown on $hbox{TiN}/hbox{SiO}_{2}/hbox{Si}$ at 300 $^{circ}hbox{C}$ but not in films grown at room temperature and annealed at 350 $^{circ}hbox{C}$. The 45-nm-thick films showed a high capacitance density and a low dissipation factor of 8.81 $hbox{fF}/muhbox{m}^{2}$ and 0.97% at 100 kHz, respectively, with a low leakage current density of 3.46 $hbox{nA}/hbox{cm}^{2}$ at 2 V. The quadratic and linear voltage coefficients of capacitance of this film were 846 $hbox{ppm}/hbox{V}^{2}$ and 137 ppm/V, respectively, with a low temperature coefficient of capacitance of 226 $hbox{ppm}/^{circ}hbox{C}$ at 100 kHz. This suggests that a BiNbO film grown on a $hbox{TiN}/ hbox{SiO}_{2}/hbox{Si}$ substrate is a good candidate material for high-performance metal–insulator–metal capacitors.