Evaluation of HfAlO high-k materials for control dielectric applications in non-volatile memories

In this paper, we evaluate the potentiality of hafnium aluminium oxide (HfAlO) high-k materials for control dielectric application in non-volatile memories. We analyze the electrical properties (conduction and parasitic trapping) of HfAlO single layers and SiO₂/HfAlO/SiO₂ triple layer stacks as a function of the HfAlO thickness and Hf:Al ratio. A particular attention is given to the electrical behaviour of the samples at high temperature, up to 250 °C. Experimental results obtained on silicon nanocrystal memories demonstrate the high advantage of HfAlO based control dielectrics on the memory performances for Fowler-Nordheim operation. Then an analytical model is presented, to simulate the program erase characteristics in the transient regime and at saturation, depending on the high-k control dielectric properties. A very good agreement is obtained between the experimental data and the simulation results.     

Electrical properties of quaternary HfAlTiO thin films grown by atomic layer deposition

Quaternary alloyed HfAlTiO thin (~ 4-5 nm) films in the wide range of Ti content have been grown on Si substrates by Atomic Layer Deposition technique, and the effect of both the film composition and the interfacial reactions on the electrical properties of HfAlTiO films is investigated. It is shown that depending on the Ti content, the permittivity and the leakage current density I_leak in HfAlTiO films vary in the range k = 18 ÷ 28 and 0.01-2.4 A cm^− 2, respectively. The incorporation of ultra thin SiN interlayer in Al/HfAlTiO/SiN/Si stack gives rise to the sharp (× 10³) decrease of the I_leak ~ 6 · 10^− 5 A/cm² at the expense of the rather low capacitance equivalent thickness ~ 0.9 nm.     

Effects of oxygen partial pressure on structural and electrical characteristics of HfAlO high-k gate dielectric grown on strained SiGe by pulsed-laser deposition

Dependence of oxygen partial pressures on structural and electrical characteristics of HfAlO (Hf:Al=1:1) high-k gate dielectric ultra-thin films grown on the compressively strained Si₈₃Ge₁₇ by pulsed-laser deposition were investigated. The microstructure and the interfacial structure of the HfAlO thin films grown under different oxygen partial pressures were studied by transmission electron microscopy, and the their electrical properties were characterized by capacitance–voltage (C−V) and conductance–voltage measurements. Dependence of interfacial layer thickness and C–V characteristics of the HfAlO films on the growth of oxygen pressure was revealed. With an optimized oxygen partial pressure, an HfAlO film with an effective dielectric constant of 16 and a low interface state density of 2.1×10¹⁰ cm⁻² eV⁻¹ was obtained.     

N_2和NH_3退火对铪铝氧栅介质C-V特性的影响

采用原子层淀积(ALD)的方法在Si(100)衬底上制备了铪铝氧(HfAlO)高介电常数介质,并研究了N2和NH3退火对于介质薄膜的影响。改变原子层淀积的工艺,制备了三组含有不同Al∶Hf原子比的铪铝氧(HfAlO)高介电常数介质。电容电压特性(C-V)测试表明,薄膜的积累电容密度随着薄膜中Al∶Hf原子比的减少而增加。实验表明,用N2和NH3对样品进行淀积后退火,可以减小等效电容厚度(CET)、降低固定正电荷密度以及减小滞回电压,从而有效地提高了介质薄膜的电学特性。     

Investigation of hafnium-aluminate alloys in view of integration as interpoly dielectrics of future Flash memories

In this paper, we evaluate the potentialities of hafnium-aluminates (HfAlO) materials as possible candidates for the interpoly dielectrics of future Flash memory devices. HfAlO layers of different thicknesses and compositions are integrated in single-layers and in Oxide/HfAlO/Oxide (OHO) triple-layer stacks, and analyzed in terms of coupling and insulating capabilities. We demonstrate that increasing the Hf content allows reducing the leakage current at high voltages but it results in a stronger leakage current at low voltages. We also show that once normalized in electric fields, the leakage current characteristics are independent of the high-k thickness. The electron conduction modes in these materials, at different temperatures, are also investigated. The activation energy increases with the Hf concentration in the HfAlO alloy, resulting in a higher leakage current at elevated temperatures. Finally, it is demonstrated that the conduction in triple-layer stacks is limited by a Poole–Frenkel conduction in the high-k layers, while the trap contribution in the case of single-layers becomes dominant when the HfAlO layer is thicker than 8 nm.