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This is a user sandbox of Nikkiesingh. You can use it for testing or practicing edits. This is not the sandbox where you should draft your assigned article for a dashboard.wikiedu.org course. To find the right sandbox for your assignment, visit your Dashboard course page and follow the Sandbox Draft link for your assigned article in the My Articles section. |
Quantum dots
editQuantum dots are extremely small semiconductors (on the scale of nanometers)[1]. They display quantum confinement in that the electrons cannot escape the “dot”, thus allowing particle-in-a-box approximations to be applied[2]. Their behavior can be described by three-dimensional particle-in-a-box energy quantization equations[2].
The energy gap of a quantum dot is the energy gap between its valence and conduction bands. This energy gap (E(r)) is equal to the band gap of the bulk material (Egap) plus the energy equation derived from particle-in-a-box, which gives the energy for electrons and holes[2]. This can be seen in the following equation, where m*e and m*h are the effective masses of the electron and hole, r is radius of the dot, and h is Plank's constant:[2]
Hence, the energy gap of the quantum dot is inversely proportional to the square of the “length of the box,” i.e. the the radius of the quantum dot[2].
Manipulation of the band gap allows for the absorption and emission of specific wavelengths of light, as energy is inversely proportional to wavelength[1]. The smaller the quantum dot, the larger the band gap and thus the shorter the wavelength absorbed[1][3].
Different semiconducting materials are used to synthesize quantum dots of different sizes and therefore emit different wavelengths of light[3]. Materials that normally emit light in the visible region are often used and their sizes are fine-tuned so that certain colors are emitted[1]. Typical substances used to synthesize quantum dots are cadmium (Cd) and selenium (Se)[1][3]. For example, when the electrons of two nanometer CdSe quantum dots relax after excitation, blue light is emitted. Similarly, red light is emitted in four nanometer CdSe quantum dots[4][1].
Quantum dots have a variety of functions including but not limited to fluorescent dyes, transistors, LEDs, solar cells, and medical imaging via optical probes[1][2].
One function of quantum dots is their use in lymph node mapping, which is feasible due to their unique ability to emit light in the near infrared (NIR) region. Lymph node mapping allows surgeons to track if and where cancerous cells exist[5].
Quantum dots are useful for these functions due to their emission of brighter light, excitation by a wide variety of wavelengths, and higher resistance to light than other substances[5][1].
Note: the above was a fully collaborative effort between Nikkie Singh and Kelsey Williams.
- ^ a b c d e f g h Rice, C.V.; Griffin, G.A. (2008). "Simple Syntheses of CdSe Quantum Dots". Journal of Chemical Education. 85 (6): 842. Retrieved 5 November 2016.
- ^ a b c d e f "Quantum Dots : a True "Particle in a Box" System". PhysicsOpenLab. 20 November 2015. Retrieved 5 November 2016.
- ^ a b c Overney, René M. "Quantum Confinement" (PDF). University of Washington. Retrieved 5 November 2016.
- ^ Zahn, Dietrich R.T. "Surface and Interface Properties of Semiconductor Quantum Dots by Raman Spectroscopy" (PDF). Technische Universität Chemnitz. Retrieved 5 November 2016.
- ^ a b Bentolila, Laurent A.; Ebenstein, Yuval (2009). "Quantum Dots for In Vivo Small-Animal Imaging". Journal of Nuclear Medicine. 50 (4): 493–496. Retrieved 5 November 2016.