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CIS strategy-Based Image-building of MBA Education
SUN Xin-bo,SONG You-qiang,CHEN Fa-dong 인하대학교 정석물류통상연구원 2009 인하대학교 정석물류통상연구원 학술대회 Vol.2009 No.10
At present, the competition of China’s MBA education is becoming more and more intense. Strengthening the image-building of MBA education, importing CIS strategy into MBA education, improving the core competitiveness of MBA education, and building the brand of MBA education, should become an important strategic choice to the development of MBA education. From referencing the connotation of enterprise CIS, this paper describes the significance and procedures to import the CIS strategy into MBA education, proposes some proposals about establishing and implementing MBAIS strategy, and puts forward the specific case that Northeastern University imports MBAIS into MBA education.
Shuai Huang,Xiumin Xie,Qiang Xu,Xinhua Zhao,Guangwei Deng,Qiang Zhou,You Wang,Hai-Zhi Song 한국광학회 2020 Current Optics and Photonics Vol.4 No.6
A practical single photon source for fiber-based quantum information processing is still lacking. As a possible 1.55-µm quantum-dot single photon source, an InGaAsP/InP-air-aperture micropillar cavity is investigated in terms of fabrication tolerance. By properly modeling the processing uncertainty in layer thickness, layer diameter, surface roughness and the cavity shape distortion, the fabrication imperfection effects on the cavity quality are simulated using a finite-difference time-domain method. It turns out that, the cavity quality is not significantly changing with the processing precision, indicating the robustness against the imperfection of the fabrication processing. Under thickness error of ±2 nm, diameter uncertainty of ±2%, surface roughness of ±2.5 nm, and sidewall inclination of 0.5°, which are all readily available in current material and device fabrication techniques, the cavity quality remains good enough to form highly efficient and coherent 1.55-µm single photon sources. It is thus implied that a quantum dot contained InGaAsP/InP-air-aperture micropillar cavity is prospectively a practical candidate for single photon sources applied in a fiber-based quantum information network.