Chemical interface analysis of as grown HfO2 ultrathin films on SiO2

Maunoury, C.; Dabertrand, K.; Martínez, E.; Saadoune, M.; Lafond, D.; Pierre, F.; Renault, O.; Lhostis, S.; Bailey, Paul; Noakes, T.C.Q.; Jalabert, D.

doi:10.1063/1.2435061

Cited by 27 publications

(21 citation statements)

References 37 publications

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“…Since this shift is equal to that of neither Si 4+ nor S 3+ , and being very close to that of Si 4+ , this can be inferred as the oxide containing Hf-O-Si, i.e., Hf silicate ͑HfSi x O y ͒. [26][27][28] The existence of this thick layer was also supported from the FTIR absorption spectrum ͑Fig. 2͒.…”

Section: Si Depth Profile Of the Filmmentioning

confidence: 69%

“…The chemical shift for Si 3+ , i.e., the difference in the binding energy of the component and that of elemental Si, is generally obtained at about 2.48-2.65 eV far from the position of elemental Si, i.e., 99.3 eV. 26 This chemical shift was, however, obtained ϳ3.4-3.7 eV for deeper layers of the oxide. Since this shift is equal to that of neither Si 4+ nor S 3+ , and being very close to that of Si 4+ , this can be inferred as the oxide containing Hf-O-Si, i.e., Hf silicate ͑HfSi x O y ͒.…”

Section: Si Depth Profile Of the Filmmentioning

confidence: 90%

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Interfacial and structural properties of sputtered HfO2 layers

Aygün

Yıldız

2009

Journal of Applied Physics

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Magnetron sputtered HfO2 layers formed on a heated Si substrate were studied by spectroscopic ellipsometer (SE), x-ray diffraction (XRD), Fourier transform infrared (FTIR), and x-ray photoelectron spectroscopy (XPS) depth profiling techniques. The results show that the formation of a SiO x suboxide layer at the HfO2 /Si interface is unavoidable. The HfO2 thickness and suboxide formation are highly affected by the growth parameters such as sputtering power, O2 /Ar gas ratio during sputtering, sputtering time, and substrate temperature. XRD spectra show that the deposited film has (111) monoclinic phase of HfO2, which is also supported by FTIR spectra. The atomic concentration and chemical environment of Si, Hf, and O have been measured as a function of depth starting from the surface of the sample by XPS technique. It shows that HfO2 layers of a few nanometers are formed at the top surface. Below this thin layer, Si-Si bonds are detected just before the Si suboxide layer, and then the Si substrate is reached during the depth profiling by XPS. It is clearly understood that the highly reactive sputtered Hf atoms consume some of the oxygen atoms from the underlying SiO2 to form HfO2, leaving Si-Si bonds behind

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Section: Si Depth Profile Of the Filmmentioning

confidence: 69%

Section: Si Depth Profile Of the Filmmentioning

confidence: 90%

Interfacial and structural properties of sputtered HfO2 layers

Aygün

Yıldız

2009

Journal of Applied Physics

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“…[20] Indeed, HfO 2 -based high-k dielectrics have emerged as leading candidates to replace SiO 2 for scaling below the 65 nm node in advanced metal-oxide-semiconductor applications. Typical processing routes for HfO 2 include atomic layer deposition, [21] chemical vapor deposition, [22] and physical vapor deposition. Although these techniques achieve highquality films with nanometer precision, they each have drawbacks and all require expensive high vacuum equipment.…”

Section: à2mentioning

confidence: 99%

π‐σ‐Phosphonic Acid Organic Monolayer/Sol–Gel Hafnium Oxide Hybrid Dielectrics for Low‐Voltage Organic Transistors

et al. 2008

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Anthryl‐alkyl‐PA (π‐σ‐PA) self‐assembled monolayers (SAMs)/hafnium oxide (HfO2) hybrid dielectrics have been integrated into organic thin film transistors (OTFTs) to achieve operating voltages under −1.5 V. Using π‐σ‐PA SAMs on sol–gel processed HfO2, pentacene‐based OTFTs possess low subthreshold slopes (100 mV dec−1), high on–off current ratios (105–106), and hole mobilities as high as 0.22 cm2 V−1 s−1.

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“…[7][8][9] The common high-κ dielectric is inorganic metal-oxides in general. [10][11][12][13][14][15][16] Up to now, it still is of great importance to develop novel high-κ materials as gate insulator, especially organic high-κ dielectric. Recently, it is reported that organometallic lanthanide complexes, a kind of neutral mononuclear molecule-based materials, have the merit of good thermal stability, high dielectric constants (high-κ), easy thin film formation by thermal evaporation method.…”

Section: Introductionmentioning

confidence: 99%

Low-voltage organic field-effect transistors based on novel high-κ organometallic lanthanide complex for gate insulating materials

Liu

Zhang

et al. 2014

AIP Advances

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A novel high-κ organometallic lanthanide complex, Eu(tta)3L (tta=2-thenoyltrifluoroacetonate, L = 4,5-pinene bipyridine), is used as gate insulating material to fabricate low-voltage pentacene field-effect transistors (FETs). The optimized gate insulator exhibits the excellent properties such as low leakage current density, low surface roughness, and high dielectric constant. When operated under a low voltage of −5 V, the pentacene FET devices show the attractive electrical performance, e.g. carrier mobility (μFET) of 0.17 cm2 V−1 s−1, threshold voltage (Vth) of −0.9 V, on/off current ratio of 5 × 103, and subthreshold slope (SS) of 1.0 V dec−1, which is much better than that of devices obtained on conventional 300 nm SiO2 substrate (0.13 cm2 V−1 s−1, −7.3 V and 3.1 V dec−1 for μFET, Vth and SS value when operated at −30 V). These results indicate that this kind of high-κ organometallic lanthanide complex becomes a promising candidate as gate insulator for low-voltage organic FETs.

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Chemical interface analysis of as grown HfO2 ultrathin films on SiO2

Cited by 27 publications

References 37 publications

Interfacial and structural properties of sputtered HfO2 layers

Interfacial and structural properties of sputtered HfO2 layers

π‐σ‐Phosphonic Acid Organic Monolayer/Sol–Gel Hafnium Oxide Hybrid Dielectrics for Low‐Voltage Organic Transistors

Low-voltage organic field-effect transistors based on novel high-κ organometallic lanthanide complex for gate insulating materials

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