Researchers monitored the diameter of semiconductor quantum dots in real time by observing the wavelength of the emitted light.
Luminescence is the outcome of a process where an object absorbs light at one wavelength and re-emits it at a different wavelength. During this process, electrons in the material’s ground state absorb light and become excited to a higher energy state. After a specific period, unique to each excited state, the electrons return to lower energy states, including the ground state, and emit light. This phenomenon is utilized in a wide range of technological applications, involving highly efficient and reproducible emitting devices that can be easily miniaturized.
The materials with the highest luminescence efficiency include quantum dots (QDs), currently used in high-resolution displays, LEDs, solar panels, and sensors of various kinds, such as those used for precision medical imaging. Functionalization of the surface of QDs with various types of molecules permits interaction with cellular structures or other molecules of interest for the purpose of investigating molecular-level biological processes.
Quantum Confinement in Quantum Dots
QDs are semiconductor nanoparticles whose emissive characteristics are directly linked to dot size, owing to the phenomenon of quantum confinement. For this reason, monitoring and control of crystal growth during the synthesis of QDs in solution permits intelligent planning of the desired luminescence. In an article published in the journal Scientific Reports, researchers led by Andrea de Camargo, a professor at the University of São Paulo’s São Carlos Physics Institute (IFSC-USP) in Brazil, and collaborators at Kiel University in Germany present a novel approach to the monitoring of QD formation.
“We used cadmium telluride [CdTe] as a model system and controlled nanoparticle growth in a heated aqueous solution via in situ luminescence analysis,” says Pedro Felipe Garcia Martins da Costa, a PhD candidate at IFSC-USP and first author of the article.
The technique enables scientists to see what is happening in the solution in real-time without affecting QD synthesis, so that they can monitor crystal growth by observing the color (wavelength) of the light emitted. “QDs are synthesized by mixing cadmium (Cd2+) and tellurium (Te2-) precursor solutions in the presence of a size control reagent. The temperature is raised and the chemical reaction begins via telluride and cadmium ion clustering. As the reaction proceeds, additional units of CdTe join the cluster spherically in a process known as self-assembly. Nanoparticle size can be estimated thanks to rapid and precise monitoring of the emission frequencies. QDs of CdTe with a diameter of 1-2 nanometers [nm] emit in the blue and green regions of the visible spectrum. Larger QDs, measuring 4-5 nm, emit at lower frequencies, as yellow and red respectively,” says Leonnam Gotardo Merizio, a postdoctoral researcher at IFSC-USP and second author of the article.
Advantages of the In Situ Technique
According to Costa, the novel method has several advantages over the conventional synthesis strategy. “In the conventional technique, you have to take small samples of the solution to measure QD size, but the in situ technique lets you do so as the process is underway, without having to interfere with the reaction medium to take samples so that more spectra can be obtained per unit of time, reaction volume isn’t affected, and unnecessary waste is avoided. The emission color of the QDs of interest can therefore be controlled far more precisely. The equipment that delivers the excitation light via optical fiber at the appropriate wavelength also collects the emitted light and determines its characteristic frequency in the RGB [red, green, and blue] color system. It’s worth noting that control of the RGB system is relevant to image formation in several luminescent devices, such as monitors and smartphone displays,” he explains.
QDs synthesized in this way, he added, were also characterized by means of X-ray diffraction, transmission electron microscopy, ultraviolet-visible absorption spectroscopy, and infrared vibration spectroscopy.
The existence of QDs was predicted theoretically in 1937 by Herbert Fröhlich (1905-91), a German-born British physicist. In the 1980s, Alexey Ekimov (born 1945), in what was then the Soviet Union, and Louis Brus (born 1943), in the United States, independently observed quantum confinement in semiconductor nanoparticles for the first time. In the 1990s, French-American physicist Moungi Bawendi (born 1961) developed significantly enhanced methods of QD synthesis. In 2023, Ekimov, Brus, and Bawendi were awarded the Nobel Prize for Chemistry for their work in the field.
“Quantum confinement gives QDs the capacity to confine electrons in three dimensions, making quantum phenomena more evident and characterizing them as intermediate materials between atoms, molecules, and larger crystalline arrays,” Costa says.
“Many papers have been published on the synthesis of QDs made of CdTe. Our study’s main contribution relates to the development and application of a highly versatile in situ luminescence measurement system. The methodology enabled us to infer the size of the crystalline nanoparticles and to characterize the formation of intermediate compounds in the chemical reactions by in situ association with other techniques that permit chemical and/or structural analysis [FT-IR, Raman, DRX, etc]. This evolution of synthesis optimizes chemical yields and saves energy,” Camargo says.
Reference: “Real-time monitoring of CdTe quantum dots growth in aqueous solution” by P. F. G. M. da Costa, L. G. Merízio, N. Wolff, H. Terraschke and A. S. S. de Camargo, 3 April 2024, Scientific Reports.
DOI: 10.1038/s41598-024-57810-8
The study was funded by the São Paulo Research Foundation.