Amorphous silicon oxide containing nanocrystalline silicon grain(nc-SiOx:H) films are prepared by a plasmaenhanced chemical vapor deposition technique at different negative substrate bias voltages.The influence of ...Amorphous silicon oxide containing nanocrystalline silicon grain(nc-SiOx:H) films are prepared by a plasmaenhanced chemical vapor deposition technique at different negative substrate bias voltages.The influence of the bias voltage applied to the substrate on the microstructure is investigated.The analysis of x-ray diffraction spectra evidences the in situ growth of nanocrystalline Si.The grain size can be well controlled by varying the substrate bias voltage,and the largest size is obtained at 60 V.Fourier transform infrared spectra studies on the microstructure evolutions of the nc-SiOx:H films suggest that the absorption peak intensities,which are related to the defect densities,can be well controlled.It can be attributed to the fact that the negative bias voltage provides a useful way to change the energies of the particles in the deposition process,which can provide sufficient driving force for the diffusion and movement for the species on the growing surface and effectively passivate the dangling bonds.Also the larger grain size and lower band gap,which will result in better photosensitivity,can also be obtained with a moderate substrate bias voltage of 60 V.展开更多
A novel silicon double-RESURF LDMOS structure with an improved breakdown characteristic by substrate bias technology(SB) is reported.The P-type epitaxial layer is embedded between an N-type drift region and an N-typ...A novel silicon double-RESURF LDMOS structure with an improved breakdown characteristic by substrate bias technology(SB) is reported.The P-type epitaxial layer is embedded between an N-type drift region and an N-type substrate to block the conduction path in the off-state and change the distributions of the bulk electric field.The substrate bias strengthens the charge share effect of the drift region near the source,and the vertical electric field peak under the drain is decreased,which is especially helpful in improving the vertical breakdown voltage in a lateral power device with a thin drift region.The numerical results by MEDICI indicate that the breakdown voltage of the proposed device is increased by 97%compared with a conventional LDMOS,while maintaining a low on-resistance.展开更多
Tetrahedral amorphous carbon(ta‐C)has emerged as an excellent coating material for improving the reliability of application components under high normal loads.Herein,we present the results of our investigations regar...Tetrahedral amorphous carbon(ta‐C)has emerged as an excellent coating material for improving the reliability of application components under high normal loads.Herein,we present the results of our investigations regarding the mechanical and tribological properties of a 2‐μm‐thick multilayer ta‐C coating on high‐speed steel substrates.Multilayers composed of alternating soft and hard layers are fabricated using filtered a cathodic vacuum arc with alternating substrate bias voltages(0 and 100 V or 0 and 150 V).The thickness ratio is discovered to be 1:3 for the sp2‐rich and sp3‐rich layers.The results show that the hardness and elastic modulus of the multilayer ta‐C coatings increase with the sp3 content of the hard layer.The hardness reached approximately 37 GPa,whereas an improved toughness and a higher adhesion strength(>29 N)are obtained.The friction performance(μ=0.07)of the multilayer coating is similar to that of the single layer ta‐C thick coating,but the wear rate(0.13×10^(–6) mm^(3)/(N∙m))improved under a high load of 30 N.We further demonstrate the importance of the multilayer structure in suppressing crack propagation and increasing the resistance to plastic deformation(H3/E2)ratio.展开更多
基金supported by the Key Basic Research Project of Hebei Province,China(Grant No.12963930D)the Natural Science Foundation of Hebei Province,China(Grant No.F2013201250)the Science and Technology Research Projects of the Educational Department of Hebei Province,China(Grant No.ZH2012030)
文摘Amorphous silicon oxide containing nanocrystalline silicon grain(nc-SiOx:H) films are prepared by a plasmaenhanced chemical vapor deposition technique at different negative substrate bias voltages.The influence of the bias voltage applied to the substrate on the microstructure is investigated.The analysis of x-ray diffraction spectra evidences the in situ growth of nanocrystalline Si.The grain size can be well controlled by varying the substrate bias voltage,and the largest size is obtained at 60 V.Fourier transform infrared spectra studies on the microstructure evolutions of the nc-SiOx:H films suggest that the absorption peak intensities,which are related to the defect densities,can be well controlled.It can be attributed to the fact that the negative bias voltage provides a useful way to change the energies of the particles in the deposition process,which can provide sufficient driving force for the diffusion and movement for the species on the growing surface and effectively passivate the dangling bonds.Also the larger grain size and lower band gap,which will result in better photosensitivity,can also be obtained with a moderate substrate bias voltage of 60 V.
基金Project supported by the Guangxi Natural Science Foundation of China(No.2010GXNSFB013054)the Guangxi Key Science and Technology Program of China(No.11107001-20)
文摘A novel silicon double-RESURF LDMOS structure with an improved breakdown characteristic by substrate bias technology(SB) is reported.The P-type epitaxial layer is embedded between an N-type drift region and an N-type substrate to block the conduction path in the off-state and change the distributions of the bulk electric field.The substrate bias strengthens the charge share effect of the drift region near the source,and the vertical electric field peak under the drain is decreased,which is especially helpful in improving the vertical breakdown voltage in a lateral power device with a thin drift region.The numerical results by MEDICI indicate that the breakdown voltage of the proposed device is increased by 97%compared with a conventional LDMOS,while maintaining a low on-resistance.
基金This work was supported by the Fundamental Research Program of the Korea Institute of Materials Science(KIMS/PNK7000)the Fundamental R&D Program of the Ministry of Science,Information&Communication Technology(ICT)Future Planning in Republic of Korea.
文摘Tetrahedral amorphous carbon(ta‐C)has emerged as an excellent coating material for improving the reliability of application components under high normal loads.Herein,we present the results of our investigations regarding the mechanical and tribological properties of a 2‐μm‐thick multilayer ta‐C coating on high‐speed steel substrates.Multilayers composed of alternating soft and hard layers are fabricated using filtered a cathodic vacuum arc with alternating substrate bias voltages(0 and 100 V or 0 and 150 V).The thickness ratio is discovered to be 1:3 for the sp2‐rich and sp3‐rich layers.The results show that the hardness and elastic modulus of the multilayer ta‐C coatings increase with the sp3 content of the hard layer.The hardness reached approximately 37 GPa,whereas an improved toughness and a higher adhesion strength(>29 N)are obtained.The friction performance(μ=0.07)of the multilayer coating is similar to that of the single layer ta‐C thick coating,but the wear rate(0.13×10^(–6) mm^(3)/(N∙m))improved under a high load of 30 N.We further demonstrate the importance of the multilayer structure in suppressing crack propagation and increasing the resistance to plastic deformation(H3/E2)ratio.
