Lightly Al-doped Ta2O5: Electrical properties and mechanisms of conductivity

Lightly Al-doped Ta₂O₅ films (10;15 nm) obtained by rf sputtering have been studied with respect to their dielectric and electrical properties. The formed metal-high-k dielectric-semiconductor capacitors have been characterized by capacitance-voltage and temperature-dependent current-voltage characteristics. It was established that the introduction of small amount (5 at.%) Al into the matrix of Ta₂O₅ improves dielectric constant, introduces negative oxide charge, suppresses deep oxygen-vacancy centers in Ta₂O₅ but creates shallow traps and changes the dominant conduction mechanism in the stacks. The doping produces more leaky films at room temperature and lower current at high temperature as compared to the case of pure Ta₂O₅. It is concluded that the strong contribution of tunneling processes through shallow traps in the conductivity of doped films could explain the observed current degradation at room temperature and its improved temperature stability at high temperatures. The energy levels of the traps responsible for the current transport are estimated.     

Hf-doped Ta2O5 stacks under constant voltage stress

The stress-induced leakage current in Hf-doped Ta₂O₅ layers (7; 10 nm) under constant voltage stress at gate injection was investigated in order to assess the mechanisms of conduction, the traps involved and the effect of Hf doping. The amount of Hf is found to affect the conduction mechanisms, the temperature dependence of the leakage current and the current response to the stress. A significant leakage current increase is observed only when the stress voltage and/or stress time exceed the corresponding threshold values, where the charge trapping at the pre-existing traps dominates below and defect generation above these threshold values. The energy levels of the traps responsible for the current transport are estimated. The stress effect on dominant conduction mechanisms appears quite weak, and the nature of the traps controlling the current transport before and after the stress seems to be nearly identical. The results indicate that the constant voltage stress affects the pre-existing traps in Hf-doped Ta₂O₅ and modifies their parameters, but there is no evidence for stress-induced generation of traps with completely new nature different from oxygen-vacancy related defects.     

Influence of the metal electrode on the characteristics of thermal Ta2O5 capacitors

The effect of various electrodes (Al, W, TiN) deposited by evaporation (Al) and sputtering (W, TiN) on the electrical characteristics of thermal thin film (15-35 nm) Ta₂O₅ capacitors has been investigated. The absolute level of leakage currents, breakdown fields, mechanism of conductivity, dielectric constant values are discussed in the terms of possible reactions between Ta₂O₅ and electrode material as well as electrode deposition process-induced defects acting as electrically active centers. The dielectric constant values are in the range 12-26 in dependence on both Ta₂O₅ thickness and gate material. The results show that during deposition of TiN and Al a reaction that worsens the properties of Ta₂O₅ occurs while there is not an indication for detectable reduction of Ta₂O₅ when top electrode is W, and the leakage current is 5-7 orders of magnitude lower as compared to Al and TiN-electroded capacitors. The high level of leakage current for TiN and Al gate capacitors are related to the radiation defects generated in Ta₂O₅ during sputtering of TiN, and damaged interface at the electrode due to a reaction between Al and Ta₂O₅, respectively. It is demonstrated that the quality of the top electrode affects the electrical characteristics of the capacitors and the sputtered W is found to be the best. The sputtered W gate provides Ta₂O₅ capacitors with a good quality: the current density <7 × 10⁻¹⁰ A/cm² at 1 V (0.7 MV/cm, 15 nm thick Ta₂O₅). W deposition is not accompanied by an introduction of a detectable damage leading to a change of the properties of the initial as-grown Ta₂O₅ as in the case of TiN electrode. Damage introduced during TiN sputtering is responsible for current deterioration (high leakage current) and poor breakdown characteristics. It is concluded that the sputtered W top electrode is a good candidate as a top electrode of storage capacitors in dynamic random access memories giving a stable contact with Ta₂O₅, but sputtering technique is less suitable (favorable) for deposition of TiN as a metal electrode due to the introduction of radiation defects causing both deterioration of leakage current and poor breakdown characteristics.     

Conduction mechanisms in Ta2O5 stack in response to rapid thermal annealing

The influence of the rapid thermal annealing (RTA) in vacuum at 1000 °C on the leakage current characteristics and conduction mechanisms in thermal Ta₂O₅ (7-40 nm) on Si has been studied. It was established that the effect of RTA depends on both the initial parameters of the films (defined by the oxidation temperature and film thickness) and annealing time (15-60 s). The RTA tends to change the distribution and the density of the traps in stack, and this reflects on the dielectric and leakage properties. The thinner the film and the poorer the oxidation, the more susceptible the layer to heating. The short (15 s) annealing is effective in improving the leakage characteristics of poorly oxidized samples. The RTA effect, however, is rather deleterious than beneficial, for the thinner layers with good oxygen stoichiometry. RTA modifies the conduction mechanism of Ta₂O₅ films only in the high-field region. The annealing time has strong impact on the appearance of a certain type of reactions upon annealing resulting to variation of the ratio between donors and traps into Ta₂O₅, causing different degree of compensation, and consequently to domination of one of the two mechanisms at high fields (Schottky emission or Poole-Frenkel effect). Trends associated with simultaneous action of annealing and generation of traps during RTA processing, and respectively the domination of one of them, are discussed.     

High-k HfO2-Ta2O5 mixed layers: Electrical characteristics and mechanisms of conductivity

Electrical properties of mixed HfO₂-Ta₂O₅ films (10;15 nm) deposited by rf sputtering on Si have been studied from the view point of their applications as high-k layers, by standard capacitance-voltage and temperature dependent current-voltage characteristics. The effect of HfO₂ addition to the Ta₂O₅ is thickness dependent and the thicker layers exhibit advantages over the pure Ta₂O₅ (higher dielectric constant, enhanced charge storage density and improved interface quality). The process of HfO₂ and Ta₂O₅ mixing introduces negative oxide charge, tends to creates shallow bulk traps and modifies the dominant conduction mechanisms in the stack capacitors as compared to the Ta₂O₅-based one (a contribution of tunneling processes through traps located below the conduction band of mixed layers to the leakage current in the HfO₂-Ta₂O₅ stacks is observed). The traps involved in both Poole-Frenkel and tunneling processes are identified.     

Constant current stress-induced leakage current in mixed HfO2-Ta2O5 stacks

The electrical characteristics of HfO₂-Ta₂O₅ mixed stacks under constant current stress (CCS) at gate injection with 20 mA/cm² and stressing times of 50 and 200 s have been investigated. A very weak effect of the stress on the global dielectric constant, on fast and slow states in the stack as well as on the dominant conduction mechanism is detected. The most sensitive parameter to the CCS is the leakage current. The stress-induced leakage current (SILC) is voltage and thickness dependent. The pre-existing traps govern the trapping kinetics and are a key parameter to evaluate the stress response. Two processes - positive charge build-up and new bulk traps generation - are suggested to be responsible for SILC: the domination of one of them depends on both the film thickness and the stressing time. The positive charge build-up is localized close to the gate electrode implying gate-induced defects could be precursors for it. It is established that unlike the case of single SiO₂ layer, the bulk traps closer to the gate electrode control SILC in the mixed Ta₂O₅-HfO₂-based capacitors.     

Influence of oxidation temperature on the microstructure and electrical properties of Ta2O5 on Si

The effect of the oxidation temperature (673-873 K) on the microstructural and electrical properties of thermal Ta₂O₅ thin films on Si has been studied. Auger electron spectroscopy and X-ray photoelectron spectroscopy results revealed that the films are non-stoichiometric in the depth; an interfacial transition layer between tantalum oxide and Si substrate, containing presumably SiO₂ was detected. It has been found by X-ray diffraction that the amorphous state of Ta₂O₅ depends on both the oxidation temperature and the thickness of the films—the combination of high oxidation temperature (>823 K) and thickness smaller than 50 nm is critical for the appearance of a crystal phase. The Ta₂O₅ layers crystallize to the monoclinic phase and the temperature of the phase transition is between 773 and 823 K for the thinner layers (<50 nm) and very close to 873 K for the thicker ones. The electrical characterization (current/voltage; capacitance/voltage) reveals that the optimal oxidation temperature for achieving the highest dielectric constant (∼32) and the lowest leakage current (10⁻⁸ A/cm² at 1 MV/cm applied field) is 873 K. The results imply that the poor oxidation related defects are rather the dominant factor in the leakage current than the crystallization effects.     

Investigation of Ta2O5/SiO2/4H-SiC MIS capacitors

Tantalum pentoxide (Ta₂O₅) deposited by pulsed DC magnetron sputtering technique as the gate dielectric for 4H-SiC based metal-insulator-semiconductor (MIS) structure has been investigated. A rectifying current-voltage characteristic was observed, with the injection of current occurred when a positive DC bias was applied to the gate electrode with respect to the n type 4H-SiC substrate. This undesirable behavior is attributed to the relatively small band gap of Ta₂O₅ of around 4.3 eV, resulting in a small band offset between the 4H-SiC and Ta₂O₅. To overcome this problem, a thin thermal silicon oxide layer was introduced between Ta₂O₅ and 4H-SiC. This has substantially reduced the leakage current through the MIS structure. Further improvement was obtained by annealing the Ta₂O₅ at 900 °C in oxygen. The annealing has also reduced the effective charge in the dielectric film, as deduced from high frequency C-V measurements of the Ta₂O₅/SiO₂/4H-SiC capacitors.     

New TIT capacitor with ZrO2/Al2O3/ZrO2 dielectrics for 60 nm and below DRAMs

New ZrO₂/Al₂O₃/ZrO₂ (ZAZ) dielectric film was successfully developed for DRAM capacitor dielectrics of 60 nm and below technologies. ZAZ dielectric film grown by ALD has a mixture structure of crystalline phase ZrO₂ and amorphous phase Al₂O₃ in order to optimize dielectric properties. ZAZ TIT capacitor showed small Tox.eq of 8.5 Å and a low leakage current density of 0.35 fA/cell, which meet leakage current criteria of 0.5 fA/cell for mass production. ZAZ TIT capacitor showed a smaller cap leak fail bit than HAH capacitor and stable leakage current up to 550 °C anneal. TDDB (time dependent dielectric breakdown) behavior reliably satisfied the 10-year lifetime criteria within operation voltage range.     

Evidence for a conduction through shallow traps in Hf-doped Ta2O5

The influence of Hf-doping on the leakage currents and conduction mechanisms in Ta₂O₅ stacks is investigated. The current conduction mechanisms as well as the traps participating in them are identified by temperature dependent current–voltage measurements. A strong dependence of the dominant conduction mechanism on the doping and the layer thickness is established. Hf-doping alters substantially the dominant mechanism of conductivity in pure Ta₂O₅. Conduction in Hf-doped Ta₂O₅ is performed through shallower traps as compared to the pure Ta₂O₅, which results in a higher leakage current in the former stacks. A certain trap can assist in different conduction processes depending on the layer thickness and the applied field. It is found that Hf-doping passivates oxygen vacancies in Ta₂O₅ and the deep traps level associated with this defect is not observed in Hf-doped samples. The origin of the detected traps is also commented.     

Physical and electrical characteristics of the high-k Nd2O3 polyoxide deposited on polycrystalline silicon

In this study, the electrical and physical characteristics of the high-k Nd₂O₃ polyoxides by RF sputtering system deposited on the polycrystalline silicon have been investigated. It can be seen that the high-k Nd₂O₃ polyoxides with post rapid thermal annealing (RTA) at 900 °C can show higher breakdown electric field, smaller gate voltage shift and larger charge-to-breakdown in comparison with the as-deposited polyoxide. This is believed to be due to the post-RTA treatment can passivate the defects and trap states to terminate the dangling bonds and traps existed in the high-k Nd₂O₃ dielectric and the interface between high-k film and polysilicon.     

Structural and optical properties on thulium-doped LHPG-grown Ta2O5 fibres

Structural, spectroscopic and dielectric properties of thulium-doped laser-heated pedestal Ta₂O₅ as-grown fibres were studied. Undoped samples grow preferentially with a single crystalline monoclinic structure. The fibre with the lowest thulium content (0.1 at%) also shows predominantly a monoclinic phase and no intra-4f¹² Tm³⁺ recombination was observed. For sample with the highest thulium amount (1.0 at%), the appearance of a dominant triclinic phase as well as intraionic optical activation was observed. The dependence of photoluminescence on excitation energy allows identification of different site locations of Tm³⁺ ions in the lattice. The absence of recombination between the first and the ground-state multiplets as well as the temperature dependence of the observed transitions was justified by an efficient energy transfer between the Tm³⁺ ions. Microwave dielectric properties were investigated using the small perturbation theory. At a frequency of 5 GHz, the undoped material exhibits a dielectric permittivity of 21 and for thulium-doped Ta₂O₅ samples it decreases to 18 for the highest doping concentration. Nevertheless, the dielectric losses maintain a very low value.     

Breakdown characteristics of nFETs in inversion with metal/HfO2 gate stacks

Time zero and time dependent dielectric breakdown (TZBD and TDDB) characteristics of atomic layer deposited (ALD) TiN/HfO₂ high-κ gate stacks are studied by applying ramped and constant voltage stress (RVS and CVS), respectively, on the n-channel MOS devices under inversion conditions. For the gate stacks with thin high-κ layers (?3.3 nm), breakdown (BD) voltage during RVS is controlled by the critical electric field in the interfacial layer (IL), while in the case of thicker high-κ stacks, BD voltage is defined by the critical field in the high-κ layer. Under low gate bias CVS, one can observe different regimes of the gate leakage time evolution starting with the gate leakage current reduction due to electron trapping in the bulk of the dielectric to soft BD and eventually hard BD. The duration of each regime, however, depends on the IL and high-κ layer thicknesses. The observed strong correlation between the stress-induced leakage current (SILC) and frequency-dependent charge pumping (CP) measurements for the gate stacks with various high-κ thicknesses indicates that the degradation of the IL triggers the breakdown of the entire gate stack. Weibull plots of time-to-breakdown (T_BD) suggest that the quality of the IL strongly affects the TDDB characteristics of the Hf-based high-κ gate stacks.     

Trap parameters and conduction mechanism in HfO2-Ta2O5 mixed stacks in response to microwave irradiation

The effect of microwave treatment at room temperature on the leakage current and mechanisms of conductivity in mixed HfO₂-Ta₂O₅ (10 nm) stacks has been studied by temperature dependent (20-100 °C) current-voltage characteristics. It was established that the short term irradiation (∼6 s) affects the electrically active centers in the mixed oxide, provokes modification of the dominant conduction mechanism at about and above 1 MV/cm and improves the temperature stability of capacitors manifesting as low level of current at high temperatures (current decrease up to two orders of magnitude at 100 °C after the treatment is detected). The traps involved in the conduction processes in pre- and post-irradiation capacitors are identified. The longer exposure (10-15 s) is effective in a significant reduction of leakage current (up to 3-4 orders of magnitude in wide range of applied voltages). The potential of microwave treatment at room temperature as technological step for improving the temperature stability of leakage current in high-k stacked capacitors is discussed.     

Analysis of reliability characteristics of high capacitance density MIM capacitors with SiO2-HfO2-SiO2 dielectrics

In this paper, reliability as well as electrical properties of high capacitance density metal-insulator-metal (MIM) capacitor with hafnium-based dielectric is analyzed in depth. The fabricated MIM capacitor exhibits not only high capacitance density but also low voltage coefficient of capacitance (VCC) and low temperature coefficient of capacitance (TCC). It also has a low leakage current level of about ∼1 nA/cm² at room temperature and 1 V. However, it is shown that voltage linearity has a different dependence on the polarity of applied bias as temperature increases maybe due to the bulk traps between the metal electrode and high-k dielectric interface. In addition, the effect of charge trapping and de-trapping on the voltage linearity is analyzed under constant voltage stress.     

Effects of O2 plasma treatment on the electric and dielectric characteristics of Ba0.7Sr0.3TiO3 thin films

The effects of the O₂ plasma treatment on the electric and dielectric characteristics of Ba_0.7Sr_0.3TiO₃ (BST) thin films were investigated. As a result of the exposure of the as-deposited or the annealed BST films to the O₂ plasma, the leakage current density of the BST films can be improved. Typically, the leakage current density can decrease by three orders of magnitude as compared that of the non-plasma treated sample at an applied voltage of 1.5 V. It is found that the plasma treatment changes the surface morphology. The capacitance of the BST films was reduced by 10%30%. The improvement of the leakage current density and the reduction of a dielectric constant for the plasma treated samples could be attributed to the reduction of carbon contaminations of BST thin films. The 10 year life time of the time-dependent dielectric breakdown (TDDB) studies indicates that all the samples have a life time of over 10 years of operation at a voltage bias of 1 V.     

Effects of the metal gate on the stress-induced traps in Ta2O5/SiO2 stacks

The degradation of Ta₂O₅-based (10 nm) stacked capacitors with different top electrodes, (Al, W, Au) under constant current stress has been investigated. The variation of electrical characteristics after the stress is addressed to gate-induced defects rather than to poor-oxidation related defects. The main wearout parameter in Ta₂O₅ stacks is bulk-related and a generation only of bulk traps giving rise to oxide charge is observed. The post-stress current–voltage curves reveal that stress-induced leakage current (SILC) mode occurs in all capacitors and the characteristics of pre-existing traps define the stress response. The results are discussed in terms of simultaneous action of two competing processes: negative charge trapping in pre-existing electron traps and stress-induced positive charge generation, and the domination of one of them in dependence on both the stress level and the gate used. The charge build-up and the trapping/detrapping processes modify the dominant conduction mechanism and the gate-induced defects are precursors for device degradation. It is concluded that the impact of the metal gate on the ultimate reliability of high-k stacked capacitors should be strongly considered.     

Dependence of electrical properties on interfacial layer of Ta2O5 films

The change in the thickness and chemical states of the interfacial layer and the related electrical properties in Ta₂O₅ films with different annealing temperatures were investigated. The high-resolution transmission electron microscopy and X-ray photoelectron spectroscopy analyses revealed that the 700 °C-annealed Ta₂O₅ film remained to be amorphous and had the thinnest interfacial layer which was caused by Ta-silicate decomposition to Ta₂O₅ and SiO₂. In addition, the electrical properties were improved after annealing treatments. Our results suggest that an annealing treatment at 700 °C results in the highest capacitance and the lowest leakage current in Ta₂O₅ films due to the thinnest interfacial layer and non-crystallization.     

Effect of microwave radiation on the properties of Ta2O5–Si microstructures

The paper presents results of the effect of microwave irradiation at room temperature on the properties of thin layers of tantalum pentoxide deposited on Si by rf sputtering. Electrical characterization is performed in conjunction with Auger electron spectroscopy and atomic force microscopy. Among exposure times used (1; 5; 10 s), treatment of about 5 s shows the best promise as an annealing step––an improvement of number of parameters of the system Ta₂O₅–Si is established (dielectric constant and surface morphology; stoichiometry and microstructure of both the bulk oxide and the interfacial transition region; electrical characteristics in terms of oxide charge density, leakage current and breakdown fields). At the same time the microwave irradiation is not accompanied by crystalization effects in Ta₂O₅ and/or additional oxidation of Si substrate. It is concluded that the short-time microwave irradiation can be used as an annealing process for Ta₂O₅–Si microstructures and it has a potential to replace the high-temperature annealing processes for high-k insulators.     

Metal gates and gate-deposition-induced defects in Ta2O5 stack capacitors

The effect of various electrodes (Al, W, TiN) deposited by evaporation (Al) and sputtering (W, TiN) on the electrical characteristics of Ta₂O₅ stack capacitors has been investigated. The leakage currents, breakdown fields, mechanism of conductivity and dielectric constant are discussed in the terms of possible reactions between Ta₂O₅ and electrode material as well as electrode-deposition-process-induced defects acting as electrically active centers. During deposition of TiN and Al a reaction that worsens the properties of Ta₂O₅ occurs while there is not an indication for detectable reduction of Ta₂O₅ when top electrode is W. The sputtered W top electrode is a good candidate as a gate of storage capacitors in DRAMs, but sputtering technique is less suitable for deposition of TiN due to the introduction of radiation defects causing deterioration of leakage current. Although some reaction between Al and Ta₂O₅ occurs, the resulting electrical properties of the capacitors are still acceptable.