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A three-necked, round-bottomed flask was used as the reaction vessel. A glass tube at the first flask-mouth to inject high-purity N2 into the reaction liquid, and the pressure in the three-necked flask was increased at the beginning of the reaction to prevent air entering. The gas was exhausted during the second flask-mouth. The glass tube was connected to the rubber tube and inserted into another beaker filled with silicone oil, to prevent the air from being sucked into the reaction flask while exhausting. It was equipped with a rubber plug and a glass tube for adding drugs at the last flask-mouth. The rubber plug was used to seal the glass tube after adding, and the NaHTe solution was extracted after completion of the reaction in the syringe. The specific operation was described as follows: first, connected the device and injected N2; second, added 30 ml deionized water and injected N2 into the water after 5 minutes; third, magnetic stirring for 10 minutes, the three-necked flask was in an oxygen-free environment; then added 2.5 g Te powder and 1.8 g NaBH4 through the stopper of the glass tube, and sealed the glass tube with a rubber plug quickly. To prevent air entering, a syringe was used and a long needle was inserted into a rubber plug at the third opening of the flask in the process of extracting the NaHTe solution after the reaction.
Using the device, the reaction at room temperature was achieved. The exhaust system was sufficient to handle hydrogen generated at the high speed, as well as the N2 provided cooling. In this paper, the new preparation method has successfully reduced the traditional harsh conditions of reaction from 10 hours at 5 ℃ to 1 hour at the room temperature and improved the quality of the NaHTe solution. The preparation quality and speed were increased, and Te source was the furthest avoided from being polluted by oxidation to the greatest extent.
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The synthetic procedure was instructed according to the method mentioned in Ref.[12] with minor modification Typically, took 500 mL of deionized water and put it into a 1000 mL three-necked flask, then added0.4565 g of CdCl2•2.5 H2O, 0.310 ml of TGA, passed in N2, and stirred. Adjusted the pH of the solution to 9 with 1 mol/L NaOH. Took 0.612 ml of the NaHTe solution which was prepared and added it into a three-necked flask, adjusted the heating temperature to 100 ℃, condensed and refluxed for 2 hours to complete the preparation of the CdTe core.
Repeated the above process twice and adjusted the pH value to 10 and 11 respectively. The condensation reflux was adjusted accordingly for 6 hours and 10 hours to prepare the CdTe core. The sample was observed under the 365 nm ultraviolet light and the color was shown in Tab.1.
Table 1. Ten kinds of the core-shell structure quantum dots
Sample number Quantum dots Size/nm Core color Cladding time S1 CdTe/CdS-1 3.2 Orange 30 min S2 CdTe/CdS-2 3.3 Orange 1 h S3 CdTe/CdS-3 3.4 Orange 2 h S4 CdTe/CdS-4 3.0 Yellow 30 min S5 CdTe/CdS-5 3.1 Yellow 1 h S6 CdTe/CdS-6 2.6 Green 30 min S7 CdTe/CdS-7 2.7 Green 1 h S8 CdTe/CdS-8 2.8 Green 2 h S9 CdTe/ZnS-9 3.5 Orange 30 min S10 CdTe/ZnS-10 3.6 Orange 1 h -
Took 100 mL CdTe solution and put it into 250 mL three-necked flask, passed in the N2 and stirred. Weighed 0.0122 g thiourea in a three-necked flask and recovered the pH of the solution to 10 with 1 mol/L NaOH. Set the temperature for 90 ℃ and started the timer when the temperature reached 90 ℃. The reflux time was 30 min, 1 h and 2 h, respectively. After the reaction, the three-necked flask was cooled to room temperature quickly with cold water.
The obtained the CdTe/CdS quantum dots solution was put into the centrifuge tube, and the ratio of the CdTe/CdS quantum dots to the ethanol in the solution was 1∶2 to 1∶4 (volume ratio), and centrifuged in a high-speed centrifuge, with the rotation speed of 10000 r/min and the time was set for 10 minutes. After repeated centrifugation, the solids were dissolved in deionized water for testing.
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The CdTe/ZnS quantum dots were synthesized and improved according to the method of Li’s group[13]. To obtain these dots, a mixture of 80 ml CdTe solution, 0.230 g ZnSO4 and 0.148 ml TGA was loaded slowly into 20 ml Na2S•9H2O aqueous solution. Molar ratio of Zn to S was 1∶1, and the molar ratio of Cd to Zn was 1∶2. The reaction occurs when stirred and heated to 80 ℃. The size of the shell is controlled with the reaction time. Then, the CdTe/ZnS quantum dots were centrifuged and purified, finally re-dispersed into the deionized water.
To sum up, the parameters of the 10 water-soluble core-shell quantum dots are shown in Tab.1
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In order to explore the influence of shell thickness, core size and shell material of the semiconductor quantum dots on UV-VIS absorption spectrum, the eight kinds of CdTe/CdS and two kinds of CdTe/ZnS semiconductor quantum dots were measured (UV-2500 UV-vis spectrometer from Shimadsu, Japan), as shown in Fig.1 and Fig.2 respectively.
The fluorescence spectrum of the CdTe/CdS and the CdTe/ZnS quantum dots under the excitation wavelength of 400 nm were obtained using the LS55 fluorescence spectrometer from Perkin Elmer, as shown in Fig.3.
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In Tab.1, the core color was observed by sampling the CdTe at the wavelength of 365 nm (the ultraviolet light) before cladding. In the same reaction temperature, the pH value of the reaction system was changed to 9.0, 10.0, 11.0, which is corresponding to the change of the time of the reflux condensation to 2 hours, 6 hours, and 10 hours. The preparation of the CdTe core was observed under the ultraviolet light at the wavelength of 365 nm, presenting green, yellow, and orange colors. The different luminescent colors indicate the different core sizes. Tab.1 shows that the core sizes increased gradually from the colors of green, yellow to orange. The overall sizes of the quantum dots in Tab.1 were estimated according to the luminescent colors.
Eight samples were the water-soluble TGA-CdTe/CdS colloidal quantum dots. The core of S1-S3 radiated orange color under the ultraviolet irradiation, the cladding time was 30 min, 1 h, and 2 h respectively. The core of S4-S5 radiated yellow color under the ultraviolet irradiation, the cladding time was 30 min and 1 h respectively. The core of S6-S8 radiated green color under the ultraviolet irradiation, the cladding time was 30 min, 1 h and 2 h respectively. Other two samples were the water-soluble TGA-CdTe/ZnS colloidal quantum dots. The core of S9-S10 radiated orange color under the ultraviolet irradiation, the cladding time was 30 min, 1 h respectively.
To be specific, it is found that the experimental results of the S6-S8 samples indicate that different cladding time causes the change of the overall size of quantum dots under the same color of the core. The overall size of quantum dots increases with the increase of the cladding time, such as the CdTe/CdS and the CdTe/ZnS core-shell quantum dots under the same core colors of orange. And the cladding time is different for 30 min and 1 h. For example, comparing the experimental results of S9 and S10 to those of S1 and S2, it is shown that the size of the CdTe/ZnS quantum dots is larger than the corresponding of the CdTe/CdS sample.
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Figure 1 illustrates the first absorption peak of position for the CdTe/CdS quantum dots. Obviously, taking the derivative of a curve, the position with the highest slope is the absorption peak. The first absorption peaks of S1-S8 were 550 nm, 555 nm, 560 nm, 540 nm, 545 nm, 510 nm, 515 nm, and 525 nm, respectively. Figure 1 shows that the quantum dots size is increased and the absorption peak is redshifts by the increase of the cladding time under the same case of the core. Similarly, in the case of the same cladding time, the size of quantum dots is increased and the absorption peak is redshifts by the increase of the core fabrication time. It is observed that the first absorption peak of S9-S10 samples is 570 nm and 580 nm in Fig.2. With the increase of the cladding time, the size of the quantum dots increases, and the absorption peak of the CdTe/ZnS quantum dots are also redshifts.
Yu’s team[14] summarized the relationship between the size of quantum dots and the first excitonic absorption peak, which can be expressed by Eq.(1). The size of S1-S10 samples is calculated, which is about 3.2 nm, 3.3 nm, 3.4 nm, 3 nm, 3.1 nm, 2.6 nm, 2.7 nm, 2.8 nm, 3.5 nm and 3.6 nm.
$$D \!=\! (9.812\;7 \times {10^{ \!-\! 7}}){\lambda ^3} \!-\! (1.714\;7 \!\times\! {10^{ \!-\! 3}}){\lambda ^2} + 1.006\;4\lambda - 194.84$$ (2-1) where, D(nm) is the size of quantum dots, and λ(nm) is the wavelength of the first excitonic absorption peak of the corresponding sample.
The properties of the core-shell quantum dots make them different from the bulk materials or atoms and molecules. As the size of the quantum dots decreases, the quantum confinement effect is enhanced. The bandgap of the semiconductor follows Eq.(2)[15].
$$E(r) = {E_g}(r = \infty ) + \frac{{{h^2}{\pi ^2}}}{{2{R^2}}}\left(\frac{1}{{{m_e}}} + \frac{1}{{{m_h}}}\right) - \frac{{1.786{\rm{e}^2}}}{{\varepsilon R}} - 0.248E_{Rvd}^*$$ (2-2) where, E(r) is the absorption bandgap of the material, Eg is the bandgap of the material, R is the particle radius, the second term is the quantum confined energy (blue shift), the third term is the Coulomb potential energy of the electron-hole pair (red shift), and the fourth term is the effective Rydberg energy.
The second term in the formula is much larger than the third and fourth terms, so that the quantum dots diameter (2R) increases and the E(r) decreases, the corresponding absorption and the luminescence spectra generate redshift.
In summary, with the increase of quantum dots size, the absorption peak is redshift; on the contrary, if the size decreases, the absorption peak will be blue shift.
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Figure 3 shows the fluorescence spectra are at the same core (CdTe) when the shell thickness increases to a certain degree (cladding time 30 min-1 h). The fluorescence intensity increases to the peak. At this time, if the shell thickness is continuously increased, the fluorescence intensity will decrease (e.g. S6, S7, S8). The fluorescence intensity also decreases when the core size is increased (e.g. S6, S4, S1), and the fluorescence spectrum is broadened. Some large cores growth—the so-called Ostwald ripening, causing the size distribution broadening and a wide emission line width. Some types of gradient core-shell structures are known for suppressing Auger recombination and possess high PL[16]. The considerable disparity in the spatial distributions of the electron and hole wavefunctions distorts the local charge neutrality of the exciton state, which makes its energy highly sensitive to the fluctuating electrostatic environment and leads to fluctuations in the emission wavelength. Besides, this increases the polar component of the exciton–phonon coupling and results in a considerable single-dot line broadening and complex emission spectra comprised of multiple phonon replicas with fluctuating intensities and spectral positions. The fluctuating local electric field also modulates the spatial distributions of the electron and hole charge densities, which leads to changes in coupling to polar vibrations, and thereby cor-related line broadening[17].
The broadening is due to the conversion of the CdTe/CdS quantum dots from type I to type II[18]. The CdTe/CdS core of type I has both bound electrons and holes, while the CdTe/CdS of type II has bound holes in the core and electrons in the shell. In the CdTe/CdS core-shell quantum dots of type II, the conduction band bottom of the core is higher than the conduction band bottom of the shell, and the excited electrons eventually transfer to the conduction band bottom of the shell; the valence band top of the core is higher than the valence band top of the shell, and the holes transfer to the valence band top of the core.
With the increase of the core size, the potential energy at the conduction band bottom of the core increases, while the potential energy at the conduction band bottom of the shell is relatively low, and the probability of electron distribution in the shell also increases. At this time, the potential energy difference between the conduction band bottom and the valence band top is decreased, so the absorption and the luminescence peaks have redshift accordingly[19]. The composite probability of excitons is reduced due to space separation, so the maximum fluorescence intensity is weakened and the fluorescence lifetime is increased[19]. For example, S1, S4 and S6 show this situation. When the shell thickness of the CdTe/ZnS increased, the fluorescence peak position has red-shift. Now that the shell thickness of ZnS reduces the number of the dangling bonds and the surface defect states on the core surface, which increases the probability of electron hole pairs recombination, thus increasing the fluorescence peak[19].
Preparation and fluorescence characteristics of CdTe/CdS and CdTe/ZnS core-shell semiconductor quantum dots
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摘要: 核壳半导体量子点材料因其在修复单量子点表面缺陷方面的特殊性能,极大地提高了量子点的光学性能而受到人们的研究。改进了CdTe核心的制作方法,使用小型三口瓶替代传统的小烧瓶作为反应容器,制备碲氢化钠,合成了不同核心尺寸、不同壳层厚度与不同壳层材料的10种CdTe/CdS、CdTe/ZnS核壳结构半导体量子点。对10种核壳结构半导体量子点材料进行紫外可见吸收光谱及荧光光谱测试,并分析其荧光特性。量子点在紫外可见波段的吸收光谱表明随着量子点尺寸的增大,吸收峰发生红移。通过实验结果与分析可推断出CdTe/CdS量子点荧光寿命和强度的不同是由于核心和壳层尺寸的不同量子点在I型和II型中相互转换;CdTe/ZnS的壳层厚度增加时,由于ZnS的壳层降低了核心外表的悬空键和表面缺陷态的数量,使电子空穴对复合机率加大,使得荧光峰位产生了红移。Abstract: Core-shell semiconductor quantum dots materials are being investigated due to their special performance in repairing surface defects for the single quantum dots and greatly improving the optical performance of quantum dots. Instead of a traditional small flask as a reaction vessel to prepare NaHTe, the preparation of the CdTe core using a three-necked flask was achieved. 10 CdTe/CdS and CdTe/ZnS core-shell semiconductor quantum dots with different core sizes, shell thicknesses and shell materials were synthesized. The UV–visible absorption and fluorescence spectrum of 10 kinds of core-shell semiconductor quantum dots materials were measured and analyzed. The absorption spectrum of quantum dots in the UV-visible band shows that with the increase of quantum dots size, the absorption peak is red-shifted. The CdTe/CdS quantum dots differ in fluorescence lifetime and intensity due to the conversion of different core and shell sizes of quantum dots between types I and II. When the shell thickness of CdTe/ZnS increases, the shell thickness of ZnS reduces the number of dangling bonds and defect states on the core surface, which increases the probability of electron-hole pairs recombination and causes the fluorescence peak red-shift.
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Key words:
- CdTe/CdS /
- CdTe/ZnS /
- core-shell quantum dots /
- fluorescence characteristic
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Table 1. Ten kinds of the core-shell structure quantum dots
Sample number Quantum dots Size/nm Core color Cladding time S1 CdTe/CdS-1 3.2 Orange 30 min S2 CdTe/CdS-2 3.3 Orange 1 h S3 CdTe/CdS-3 3.4 Orange 2 h S4 CdTe/CdS-4 3.0 Yellow 30 min S5 CdTe/CdS-5 3.1 Yellow 1 h S6 CdTe/CdS-6 2.6 Green 30 min S7 CdTe/CdS-7 2.7 Green 1 h S8 CdTe/CdS-8 2.8 Green 2 h S9 CdTe/ZnS-9 3.5 Orange 30 min S10 CdTe/ZnS-10 3.6 Orange 1 h -
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