论文信息 - Influence of the thickness variation of the SiOx layer on the Si Quantum Dots based MOSLED

Influence of the thickness variation of the SiOx layer on the Si Quantum Dots based MOSLED

The optical and electrical variation green and blue silicon quantum dot (Si-QD) based MOSLED with the different thickness of SiOx layer has been demonstrated. The turn-on voltage of the Si-QDs based MOSLED with the different RF plasma power is linearly enlarged by increasing the thickness of the SiOx layer. The turn-on electric field is still constant at 6.6x106 V/cm. The EL emission power of the blue Si-QD based MOSLED with increasing the thickness form 150 nm to 350 nm enhances from 55 nW to 470 nW due to the larger Si-QD amount from 1.5x1018 cm-3 to 4.3x1018 cm-3 in higher thickness. The blue Si-QDs based MOSLED with the SiOx thickness of 350 nm has the maximum EL power of 470 nW. The EL wavelength of the blue Si-QD based MOSLED red-shifts from 420 nm to 450 nm when the SiOx thickness increasing from 150 nm to 350 nm. The red-shifted phenomenon on EL spectra with increasing the thickness could be explained by means of the relationship between the varied Si-QD size and degraded electron conductivity. The EL wavelength of the Si-QD based MOSLED has a band filling effect phenomenon by the increment of the biased current and thickness. The distribution of Si-QD was uniform in whole SiOx layer although there existed different Si-QD size.

Gong-Ru Lin | Bo-Han Lai | Chih-Hsien Cheng

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