Your search keyword '"Feng, Qing-rong"' showing total 3 results

1. Properties of MgB2 ultra-thin films grown by hybrid physical-chemical vapor deposition

Author

Huang Xu, Wang Ya-Zhou, Feng Qing-Rong, and Sun Xuan

Subjects

Residual resistivity, Materials science, Hybrid physical-chemical vapor deposition, Analytical chemistry, General Physics and Astronomy, Deposition (phase transition), Nanotechnology, Chemical vapor deposition, Thin film, Epitaxy, Critical field, Volumetric flow rate

Abstract

We fabricate MgB 2 ultra-thin films via hybrid physical-chemical vapor deposition technique. Under the same background pressure, the same H 2 flow rate, by changing B 2 H 6 flow rate and deposition time, we fabricate a series of ultra-thin films with thickness ranging from 5 nm to 80 nm. These films grow on SiC substrate, and are all c -axis epitaxial. We study the Volmer-Weber mode in the film formation. As the thickness increases, critical transition temperature T c (0) also increases and the residual resistivity decreases. Especially, a very high T c (0) ≈ 32.8 K for the 7.5 nm film, and T c (0) ≈ 36.5 K, low residual resistivity ρ (42 K)≈ 17.7 μΩcm, and extremely high critical current density J c (0 T,4 K) ≈ 10 7 A/cm 2 , upper critical field H c2 (0) for 10 nm film are achieved. Moreover, by optimizing the H 2 flow rate, we obtain relatively smooth surface of the 10 nm epitaxial film, with a root-mean-square roughness of 0.731 nm, which makes them well qualified for device applications.

Published

2011

2. Suppression of superconductivity in epitaxial MgB2 ultrathin films.

Author

Zhang, Chen, Wang, Yue, Wang, Da, Zhang, Yan, Liu, Zheng-Hao, Feng, Qing-Rong, and Gan, Zi-Zhao

Subjects

SUPERCONDUCTIVITY, MAGNESIUM, BORON, PHOTON detectors, CHEMICAL vapor deposition, MOLECULAR beam epitaxy, THIN film research

Abstract

MgB2 ultrathin films have potential to make sensitive superconducting devices such as superconducting single-photon detectors working at relatively high temperatures. We have grown epitaxial MgB2 films in thicknesses ranging from about 40 nm to 6 nm by using the hybrid physical-chemical vapor deposition method and performed electrical transport measurements to study the thickness dependence of the superconducting critical temperature Tc. With reducing film thickness d, although a weak depression of the Tc has been observed, which could be attributed to an increase of disorder (interband impurity scattering) in the film, the Tc retains close to the bulk value of MgB2 (39 K), being about 35 K in the film of 6 nm thick. We show that this result, beneficial to the application of MgB2 ultrathin films and in accordance with recent theoretical calculations, is in contrast to previous findings in MgB2 films prepared by other methods such as co-evaporation and molecular-beam epitaxy, where a severe Tc suppression has been observed with Tc about one third of the bulk value in films of ∼5 nm thick. We discuss this apparent discrepancy in experiments and suggest that, towards the ultrathin limit, the different degrees of Tc suppression displayed in currently obtained MgB2 films by various techniques may arise from the different levels of disorder present in the film or different extents of proximity effect at the film surface or film-substrate interface. [ABSTRACT FROM AUTHOR]

Published

2013

3. Progress in depositing MgB2 films on stainless steel substrate

Author

Li, Fen, Guo, Tao, Zhang, Kaicheng, Chen, Chinping, and Feng, Qing-rong

Subjects

*STAINLESS steel, *CHEMICAL vapor deposition, *EXTRAPOLATION, *MAGNETIC fields

Abstract

Abstract: We have made a progress in fabricating MgB2 films, ∼25μm, on the stainless steel substrate by hybrid physical–chemical vapor deposition. The superconducting transition temperature is, T C (onset)=39.6K with a transition width, ΔT =0.5K. The characterization by scanning electron microscope and X-ray diffraction indicates that its structure is polycrystalline. At T =0K, the upper critical field H C2 is determined as 15.2T by extrapolation from a polynomial fitting to the transition temperatures under various applied fields, T C(H). In the self field, the critical current density J C is determined as 3.74MA/cm2 at T =15K by a magnetic measurement according to the Bean model. [Copyright &y& Elsevier]

Published

2007