Due to quantum confinement effect, band gap of semiconductor nanocrystals (NCs) is dependent on the particle size.
由于量子限域效应,半导体纳米晶的能带宽随粒子大小而改变。
Semiconductor nanocrystals have unique optical and electrical properties, due to quantum size effect and dielectric confinement effect.
半导体纳米晶由于量子尺寸效应和介电限域效应使它们具有独特的光致发光性能。
Quantum dots (QDs), also known as semiconductor nanocrystals, have drawn significant attention for their potential as fluorescent probes in biological field.
量子点,又叫做无机纳米晶,由于其作为荧光探针在生物领域中的巨大应用前景,已引起生物学家们的广泛关注。
Due to the quantum size effect, semiconductor quantum dot nanocrystals can be used to adjust the wavelength of the luminescence center for broadband infrared emission.
半导体量子点可利用量子尺寸效应,具有可调节红外宽带发光中心波长等特点。
In the framework of the colloidal chemistry approach, high quality nanocrystals of different II-VI and III-V semiconductor materials can now be obtained.
在胶体化学进展的框架下,现已获得不同II-VI型和III-V型半导体材料的高质量纳米晶。
In the framework of the colloidal chemistry approach, high quality nanocrystals of different II-VI and III-V semiconductor materials can now be obtained.
在胶体化学进展的框架下,现已获得不同II-VI型和III-V型半导体材料的高质量纳米晶。
应用推荐