Parameter-dependent oxidation of physically sputtered Cu and the related fabrication of Cu-based semiconductor films with metallic resistivity

Su, Jiangbin; Zhang, Jianhua; Yang, Lü; Jiang, Meiping; Zhou, Lei

doi:10.1007/s40843-016-0125-y

Cited by 20 publications

(10 citation statements)

References 18 publications

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“…It can be found that the band gap of CuO thin films deposited on polished and unpolished Si wafers is estimated to be 2.03 and 1.94 eV respectively, which are both much larger than that of bulk CuO (1.2 eV). Since the band gap of a semiconductor film is affected by some factors such as quantum size or nanosize effect, doping and defect [15]. In the present case, the nanosize effect including effects of film thickness and building particle and sheet sizes, and the crystal defect in the film may both influence the band gap.…”

Section: Resultsmentioning

confidence: 86%

“…The other details and parameters can be found in [13]. It has been demonstrated that the residual O 2 in the pre-pumped vacuum chamber is the main oxygen source for the oxidation of sputtering Cu atoms [15]. Relative to the case in [13][14][15], the higher base pressure (2.0×10 −3 versus 5.0×10 −4 Pa) in this work can provide more sufficient O 2 (2.08×10 11 versus 5.2×10 10 atoms/cm 3 , four times) for the oxidation of Cu atoms, which may result in the formation of CuO rather than Cu and Cu 2 O.…”

Section: Methodsmentioning

confidence: 99%

“…It has been demonstrated that the residual O 2 in the pre-pumped vacuum chamber is the main oxygen source for the oxidation of sputtering Cu atoms [15]. Relative to the case in [13][14][15], the higher base pressure (2.0×10 −3 versus 5.0×10 −4 Pa) in this work can provide more sufficient O 2 (2.08×10 11 versus 5.2×10 10 atoms/cm 3 , four times) for the oxidation of Cu atoms, which may result in the formation of CuO rather than Cu and Cu 2 O. The as-achieved CuO thin films were then characterized by a field-emission scanning electron microscope (SEM, ZEISS SUPRA 55), a powder x-ray diffractometer (XRD, RIGAKU D/Max 2500 PC) and an ultraviolet-visible (UV-vis) spectrophotometer (METASH UV-9000S) to study their surface morphology, crystal structure and optical properties.…”

Section: Methodsmentioning

confidence: 99%

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Selective bias deposition of CuO thin film on unpolished Si wafer

Wang

et al. 2020

Mater. Res. Express

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In order to enhance the performances of CuO-based surface-sensitive materials and devices, one feasible scheme is depositing CuO thin films on textured Si wafers to enlarge the specific surface area. In this work, the bias deposition of CuO thin film on unpolished Si wafer was carried out in a RF balanced magnetron sputtering system. The as-achieved CuO thin film was further characterized with scanning electron microscope, powder x-ray diffractometer and ultraviolet-visible spectrophotometer. It was found that the CuO thin film shows a pyramid-textured film morphology consisting of composite structures: a loose and porous thinner film at the bottom of bevel, a dense and compact thicker film at the top of bevel and on the underside, and many nanosheets standing on the film surface. The tip charging effect and bevel influence were discussed to reveal the selective deposition mechanism of CuO thin film on the unpolished Si wafer. It was also demonstrated that the unpolished rough Si wafer surface seems more suitable for the crystallization of CuO along (002) orientation rather than (111) orientation. Meanwhile, the CuO thin film on unpolished Si wafer exhibits the strongest absorption at the wavelength of ∼554 nm and a band gap of 1.94 eV, both of which show redshift relative to those of CuO thin film on polished Si wafer.

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Section: Resultsmentioning

confidence: 86%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Selective bias deposition of CuO thin film on unpolished Si wafer

Wang

et al. 2020

Mater. Res. Express

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“…As a consequence, the PNFs tend to change the morphology and crystal structure of their building nanostructures thermodynamically. In addition, the valence state of Cu element in Cu2O is +1 (Cu 1+ ), which is also unstable as driven by the tendency of decreasing the free energy [14].…”

Section: Introductionmentioning

confidence: 99%

Nanoinstabilities of Cu₂O porous nanostructured films as driven by nanocurvature effect and thermal activation effect

Zhu

et al. 2019

Nanotechnology

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In this work, the instabilities at the nanoscale (i.e. nanoinstabilities) of triangular pyramids-like Cu2O porous nanostructured films (PNFs) are studied by heating treatments under different atmosphere and temperature. It is found that the nanoscale building triangular-pyramids turn round preferentially at the sharp angles and/or coalesce with their contacting ones by directional diffusion and plastic flow of atoms, which are driven by the nonuniformly-distributed surface nanocurvature. As a result, the triangular pyramids become quasi-sphere shape and the PNF evolves into a big, dense particles film. It is also observed that the heating or thermal activation effect efficiently promotes the reduction or oxidation of Cu2O pyramids and the crystallization or growth of the as-achieved Cu or CuO grains. The above physical and chemical instabilities or changes at the nanoscale of Cu2O PNFs can be well accounted for by the combined mechanism of nanocurvature effect and thermal activation effect. The nanocurvature effect can lower the energy barrier for the atom diffusion or plastic flow and lower the activation energy for the chemical reactions, while the thermal activation effect can supply the required kinetic energy or activation energy and make the atomic transportations and reactions kinetically possible. The findings reveal the evolution laws of morphology, crystal structure and composition of triangular pyramids-like Cu2O PNF during heating treatments, which can further be extended to other types of Cu2O PNFs. Also, the findings have important implications for the nanoinstabilities of Cu2O 2 PNFs-based devices, especially those working at a high temperature.

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“…In the last several years, the controllable synthesis of Cu 2 O microand nano-sized crystals with a vast array of architectures, including core-shell Cu 2 O spheres [13], hollow Cu 2 O spheres [14], and porous Cu 2 O spheres [15] has been achieved using electrodeposition method, thermal relaxation method, sonochemical method, vacuum evaporation method, γ-irradiation method, and liquid-phase reduction method [16][17][18]. Additionally, metallic copper (Cu) and copper oxide (CuO) with various structures have also received intense attention, as they can be used in catalysis, sensors, and electronics [19][20][21][22][23][24][25][26]. However, the aforementioned synthesis approaches often involve the use of surfactants, template, and high temperature and pressure to obtain morphology-controllable Cu 2 O structures, which undoubtedly increases the synthesis cost and thus limits their large-scale production.…”

Section: Introductionmentioning

confidence: 99%

Diffusion-controlled synthesis of Cu-based for the Rochow reaction

Liu

et al. 2017

Sci. China Mater.

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The properties of materials are strongly dependent on their structures. The diffusion effect is a main kinetic factor that can be used to regulate the growth and structure of materials. In this work, we developed a systematic and feasible strategy to synthesize Cu 2 O solid spheres and hexahedrons by controlling the diffusion coefficients. These Cu 2 O products can be successively transformed into corresponding Cu hollow spheres and hexahedrons as well as CuO porous spheres and hexahedrons by controlling hydrogen diffusion in hydrazine hydrate solution and controlling oxygen diffusion in air, respectively. The formation of these transformations was also discussed in detail. Tested for Rochow reaction, the as-prepared Cu 2 O solid and CuO porous spheres exhibit higher dimethyldichlorosilane selectivity and Si conversion than Cu hollow spheres, which is attributed to the active sites for CH 3 Cl adsorption formed in Cu x Si phase after the removal of oxygen atoms in Cu 2 O and CuO in the formation of dimethylchlorosilane. The present work not only develops a feasible method for preparing well shape-defined Cu 2 O solid spheres and hexahedrons but also clarifies the respective roles of Cu, Cu 2 O and CuO in dimethyldichlorosilane synthesis via Rochow reaction.

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Parameter-dependent oxidation of physically sputtered Cu and the related fabrication of Cu-based semiconductor films with metallic resistivity

Cited by 20 publications

References 18 publications

Selective bias deposition of CuO thin film on unpolished Si wafer

Selective bias deposition of CuO thin film on unpolished Si wafer

Nanoinstabilities of Cu₂O porous nanostructured films as driven by nanocurvature effect and thermal activation effect

Diffusion-controlled synthesis of Cu-based for the Rochow reaction

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Parameter-dependent oxidation of physically sputtered Cu and the related fabrication of Cu-based semiconductor films with metallic resistivity

Cited by 20 publications

References 18 publications

Selective bias deposition of CuO thin film on unpolished Si wafer

Selective bias deposition of CuO thin film on unpolished Si wafer

Nanoinstabilities of Cu2O porous nanostructured films as driven by nanocurvature effect and thermal activation effect

Diffusion-controlled synthesis of Cu-based for the Rochow reaction

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Product

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Nanoinstabilities of Cu₂O porous nanostructured films as driven by nanocurvature effect and thermal activation effect