Silicon Nanocrystals with pH-Sensitive Tunable Light Emission from Violet to Blue-Green

Abstract: We fabricated a silicon nanocrystal (NC) suspension with visible, continuous, tunable light emission with pH sensitivity from violet to blue-green. Transmission electron microscopy (TEM) images and X-ray diffraction (XRD) pattern analysis exhibit the highly crystalline nanoparticles of silicon. Photoluminescence (PL) spectra and photoluminescence excitation (PLE) spectra at different pH values, such as 1, 3, 5, 7, 9, and 11, reveal the origins of light emission from the silicon NC suspension, which includes bo… Show more

“…Indeed, Si is an indirect bandgap semiconductor and to obtain RT emission, it is necessary to have quantum confinement. Although light-emission has been obtained from porous silicon [ 41 , 42 ] and Si nanocrystals [ 43 , 44 ], these nanomaterials present several drawbacks that limit their sensing application such as aging effect and light-emission stability and intensity [ 45 , 46 ].…”

Ultrathin Silicon Nanowires for Optical and Electrical Nitrogen Dioxide Detection

“…Indeed, Si is an indirect bandgap semiconductor and to obtain RT emission, it is necessary to have quantum confinement. Although light-emission has been obtained from porous silicon [ 41 , 42 ] and Si nanocrystals [ 43 , 44 ], these nanomaterials present several drawbacks that limit their sensing application such as aging effect and light-emission stability and intensity [ 45 , 46 ].…”

Ultrathin Silicon Nanowires for Optical and Electrical Nitrogen Dioxide Detection

“…S2 †), consistent with the TEM observation and previous studies. 25 Moreover, upon the QDs being excited by light, a tunable fluorescence emission is recorded (Fig. 2B), reflecting the availability of surface traps at different energies.…”

“…The electron–hole recombination in passivated Si QDs originates from the intrinsic band edge recombination of carriers in Si QDs—and from the trapped excitons with their localization related to oxygen exposure. 25 According to the model developed by Wolkin, the redshift in the emission with increasing excitation wavelength could be ascribed to the quantum confinement effect. 27 Meanwhile, different extents of passivation could cause different barrier heights of the carriers confined in the Si QDs.…”

Observation of anodic electrochemiluminescence from silicon quantum dots for the detection of hydrogen peroxide

Highly Sensitive Fluorescence Assay for Glucose Using Amine-Terminated Silicon Quantum Dots As a Non-enzymatic Bioprobe