Abstract

SURFACES, INTERFACES, AND THIN FILMS

Oxygen ion implantation in Strontium Bismuth Tantalate thin films

L. Rico^I; B. J. Gómez^I; M. Stachiotti^{I, II}; N. Pellegri^{I, II}; J. N. Feugeas^I; O. de Sanctis^{I, II}

^IInstituto de Física Rosario (CONICET-Universidad Nacional de Rosario), Bvrd. 27 de Febrero 210 Bis, S2000EZP Rosario, Argentina

^IILaboratorio de Materiales Cerámicos, Universidad Nacional de Rosario, Pellegrini 250, S2000EZP Rosario, Argentina

ABSTRACT

Strontium Bismuth Tantalate (SBT) ferroelectric thin films have attracted considerable attention for the development of non-volatile ferroelectric random access memories (NV-FRAMs). These films, however, have a critical problem: a high processing temperature ( > 700ºC) is required for the crystallization of the perovskite phase. The thermal evolution of the SBT films prepared by Chemical Solution Deposition (CSD) techniques showed the formation of an intermediate oxygen-deficient fluorite phase at ~ 550ºC. The SBT perovskite phase crystallizes at higher temperatures. To favor an earlier perovskite crystallization, SBT thin films were implanted with oxygen ions pulses produced by a Plasma Focus (1 kJ). The samples were annealed at different temperatures in oxygen atmosphere and characterized by GI-XRD and Atomic Force Microscopy techniques. It was found that oxygen addition into the SBT structure promotes a better crystallization of the perovskite phase.

Keywords: Ferroelectric; Thin films; SBT; Oxygen implantation; Plasma focus

I. INTRODUCTION

Strontium Bismuth Tantalate (SBT) ferroelectric thin films have attracted considerable attention for the development of non-volatile ferroelectric random access memories (NV-FRAMs) due to its relatively low voltage operation, low leakage current, fast switching and good fatigue resistance with Pt bottom electrodes [1,2]. However, SBT films have some critical problems such as high processing temperatures ( > 700ºC) to be applied to semiconductor process and a low remanent polarization which is insufficient for the high density integration of FRAMs. In addition, the control of stoichiometry in SBT films is still a tricky subject because of the lost of the bismuth component with diffusion into the Pt bottom electrode or evaporation during heat-treatment. In order to circumvent these shortcomings, many strategies have been employed such as compositional changes and modifications of the synthesis conditions.

Chemical Solution Deposition (CSD) techniques are interesting routes for the evaluation of new materials and novel strategies due to their versatility, simplicity and low temperature material synthesis [3]. Recently, we reported a stable and simple chemical route for the fabrication of SBT powders [4] and thin films [5,6] using non-hydrolyzing precursors of bismuth, strontium and tantalum alkoxides as starting materials. The utilization of acetoin, one of the Hydroxyketones, as chelating agent produced a transformation path amorphous ® fluorite ® perovskite with increasing temperature without segregation of transient bismuth or appearance of secondary phases. After the elimination of the last residual organic groups, that occurs approximately at 430ºC, the crystallization of the oxygen-defective fluorite phase starts. The fluorite ® perovskite transformation takes place at ~ 600ºC, together with a small mass gain detected from Thermogravimetric Analysis (TGA) measurements [4]. This mass gain was assigned to the incorporation of oxygen atoms into the fluorite structure.Therefore, it was inferred that an oxygen gain destabilizes the intermediate fluorite phase increasing the driving force for the fluorite ® perovskite transformation.

The aim of this work is to investigate the effects of oxygen incorporation, by ion implanting, on the crystallization behaviour of SBT thin films. The oxygen implantation was performed during the fluorite phase formation.

II. EXPERIMENTAL

Tantalum ethoxide (Ta(OCH₂CH₃)₅, purity 99.99%, Aldrich) was initially dissolved in methanol under nitrogen atmosphere. Acetoin (3-Hydroxy-2-butanone, CH₃COCH(OH)CH₃, A1,795-1, Aldrich) was added to the tantalum-methanol solution (the molar ratio of the chemical modifier to tantalum ethoxide was R=4). Then, the strontium acetate [Sr(CH₃COO)₂ .1/2 H₂O, purity 99.9%, Aldrich] was added. Separately, bismuth nitrate [BI(NiO3)₃ 5H₂0, purity 99.99%, Aldrich) was dissolved in acetic acid. Finally, the bismuth solution was added dropwise to the tantalum-strontium solution with continuous stirring. The metal precursors were mixed to form a Bismuth-rich SBT solution with a target composition of Sr_0.8Bi_2.2Ta₂O₉

Platinized silicon wafers (Pt/Ti/SiO₂/Si) were used as substrates. To obtain the films, the SBT precursor solution was deposited by spin coating (3000 rpm, 30 s) inside a clean bench. The deposition of each layer was followed by thermal treatments in air, at 250ºC for 5 minutes, at 400ºC for 10 minutes and 520ºC for 20 minutes. Crack free films of 200 nm thickness (measured by AFM) were obtained.

The Oxygen implantation was performed with a Dense Plasma Focus of 1 kJ (see Fig. 1) by mounting the samples in a holder that allows locate them at 160mm in front of the anode (inner electrode) (see experimental setup in references [7,8]). The capacitors bank charge was 15kV, the pre-vacuum pressure was 70mTorr, the filling gas was oxygen and the pressure was 300mTorr. Samples were implanted with different numbers of energetic plasma pulses of 200 ns.

Finally, the oxygen implanted and non-implanted films were annealed at increasing temperatures in oxygen atmosphere for 120 minutes.

A Chemical analysis of the films was preformed using an EDS Thermo- Noran, SEM LEITZ ARM 1000. Topographic images were observed by AFM using a NanoTec ELECTRONICA equipment working in contact mode configuration, in air at room temperature. A SiN tip supported by a silicon cantilever (0.76 Nm ^{- 1} spring constant) was used. The XRD data were collected on a Phillips X'pert diffractometer using CuK_a radiation (1.5405Å) and a graphite monochromator (the step size being of 2q = 0.02º and a 2 seconds time per step) using a grazing incidence configuration (GI-XRD).

III. RESULTS

We present in Table 1 atomic oxygen/bismuth ratios obtained by EDS for SBT films without and with oxygen implantation. These ratios do not provide quantitative information because the oxygen content comes from the SBT film and also from the SiO₂ sub-layer of the substrate. Nevertheless, they provide a qualitative indication of the oxygen gain due to the implantation treatment.

AFM images of the as-prepared SBT films (at 520ºC) without and with oxygen implantation are shown in Figure 2. The non-implanted sample (hereafter called S0) exhibits the characteristic rosettes of the fluorite phase (Fig. 2a). Figures 2b and 2c show images of the samples implanted with one pulse (S1) and six pulses (S6), respectively. It is evident that the implantation of oxygen amorphize the film surface. This effect is more pronounced for the sample S6. However, the XRD spectra of the tree samples (not shown here) display similar characteristics, exhibiting a broad peak centred at around 2q=29º which corresponds to the fluorite phase.

Figures 3a, 3b and 3c show AFM images and XRD spectra (inserts) for the S0, S1 and S6 samples annealed at 600ºC. Although the XRD spectra do not denote significant differences, the implanted films show a more homogeneous and defined morphology, with larger grain sizes. Samples annealed at 640ºC (results not shown here) display larger grain sizes in comparison with the ones annealed at 600ºC, but the appearance of the SBT perovskite phase is not detected by XRD.

The XRD spectra of the S0 and S1 samples annealed at 675 ºC reveal characteristic diffraction peaks of the SBT perovskite phase (Figures 4a and 4b). However, the spectrum of the S0 sample displays less defined perovskite peaks and a more intense peak centred at 2q=33.90º, indicating the presence of a larger content of residual fluorite phase. The surface of the S1 film (insert) exhibits a more defined grain structure in comparison with the S0 sample.

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Finally, the annealing treatment at 700 ºC developed a well crystallized SBT perovskite structure in the S1 sample, without the presence of spurious phases (Fig. 5b). The S0 sample exhibits less defined perovskite peaks and also shows the presence of peaks which could be ascribed to residual fluorite phase (Fig. 5a). The S6 sample (treated with six pulses during the ion implantation) is degraded; its XRD spectrum exhibits additional peaks that could not be ascribed to any expected phase. These peaks would come from spurious phases formed at the film-substrate interface during the oxygen implantation. This indicates that the experimental set-up energy must be improved in order to control the penetration depth of oxygen ions during the implantation process.

IV. CONCLUSIONS

The effects of oxygen incorporation, by ion implanting, on the crystallization behaviour of SBT thin films were investigated. The incorporation of oxygen into the intermediate fluorite phase produces a better crystallization of the SBT perovskite phase, increasing the driving force for the fluorite ® perovskite transformation. These preliminary results indicate that the implantation of oxygen by a Plasma Focus is a promising technique to lower the processing temperature of SBT thin films.

Acknowledgement

The authors wish to acknowledge the financial support of the Agencia Nacional de Promoción Científica y Tecnológica and Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina).

Thanks to Dr. M. Ávalos,Ing. Aldo Marenzana, Ing. Guillermo Pochettino, Tec. Horacio Merayo, Tec. Daniel Castellani, Tec. Raúl Barrionuevo and to the Instituto de Física Rosario.

Received on 8 December, 2005

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