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7/11/24, 11:00 PM Moving from the visible to the infrared: developing high quality nanocrystals | Bioengineering | Illinois

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Moving from the visible to the infrared: developing high quality
nanocrystals

In This Section  7/9/2024  Amber Rose  5 min read

  

Awarded the 2023 Nobel Prize in Chemistry, quantum dots have a wide variety of
applications ranging from displays and LED lights to chemical reaction catalysis and
bioimaging. These semiconductor nanocrystals are so small—on the order of nanometers—
that their properties, such as color, are size dependent, and they start to exhibit quantum
properties. This technology has been really well developed, but only in the visible spectrum,
leaving untapped opportunities for technologies in both the ultraviolet and infrared regions
of the electromagnetic spectrum.

In new research published in Nature
Synthesis, University of Illinois at Urbana-
Champaign bioengineering professor
Andrew Smith and postdoctoral researcher
Wonseok Lee have developed mercury
selenide (HgSe) and mercury cadmium
selenide (HgCdSe) nanocrystals that
absorb and emit in the infrared, made BioE professor Andrew Smith (left) and postdoc Wonseok
Lee (right).
from already well-developed, visible
spectrum cadmium selenide (CdSe)
precursors. The new nanocrystal products retained the desired properties of the parent CdSe
nanocrystals, including size, shape and uniformity.

“This is the first example of infrared quantum dots that are at the same level of quality as the
ones that are in the visible spectrum,” Smith says.

Although nanocrystal technology has existed for more than 50 years, only nanocrystals that
Incident description operate in the visible portion of the spectrumExposed
have beendata
significantly advanced. Smith
explains, “They’re a big part of display devices. And a big part of any technology that is light
The Illinois.edu website experienced a data breach. Over
absorbing 5 thousand
or light email
emitting. There’s just been an intrinsic push to develop a technology that
Email Password Password hash
addresses were exposed, together with credential data. Leaked records include
has the biggest market at the end of the day.”
password and password hash. The validity of the data exposed couldn’t be verified.
Yet we’re still informing you about a potential data breach – but keep in mind there’s
Beyond just the market demand for visible spectrum nanocrystals, chemistry is harder for
a chance of it being a false positive.
materials in the infrared, which is longer wavelength and lower energy than light in the
visible spectrum. To achieve light absorption and emission in the infrared, heavier elements
No. of exposed accounts
that are lower on the periodic table need to be used. Chemistry with those elements is more
difficult, yielding more unwanted side reactions and less predictable reactions. They are also
5,387 prone to degradation and are susceptible to ambient changes in Powered
the environment,
Safety warning: This website has been breached or has been part of a data leak.by like water.

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7/11/24, 11:00 PM Moving from the visible to the infrared: developing high quality nanocrystals | Bioengineering | Illinois

Quantum dot nanocrystals can be made from elemental semiconductors, like silicon, or they
can be binary or ternary. Mixing two elements can yield many different properties, mixing
three elements together can yield exponentially more properties. “We have been focusing on
this one type of material, a ternary alloy—mercury cadmium selenide—because we think it
could be the ‘perfect’ material to make,” Smith says. “You could basically get any property
you want by changing the ratio of cadmium and mercury atoms. It can span this huge range
of the electromagnetic spectrum—across the entire infrared into the entire visible spectrum
—and get so many properties.”

Smith had been trying to make this material since he was in graduate school with no luck,
and even in the broader research community, there have been no reports of success, until
now. “The way we did it was taking the already perfected, visible ones—cadmium selenide,
which is considered to be the most developed quantum dot—and used it as a ‘sacrificial
mold’,” he says.

Replacing the cadmium atoms with
mercury atoms instantly shifts everything
into the infrared spectrum, with all the
desired quality retained: strong light
absorption, strong light emission and
homogeneity.

To do this, Smith and Lee had to ditch the
Schematic representation of CdSe nanocrystal exchange traditional method of synthesis for
(left) and absorption spectra showing the shift of
nanocrystals from the visible spectrum (CdSe) to the nanocrystals, which is to mix the precursor
infrared (HgSe) (right). elements together and under the right
conditions, they decompose into the
desired nanocrystal form. As it turns out, there are no conditions that anybody has found to
work for mercury, cadmium and selenide.

“Lee developed a new process called interdiffusion enhanced cation exchange,” Smith says.
“In this process, we add a fourth element, silver, which introduces defects in the material
that causes everything to mix together homogeneously. And that solved the whole problem.”

While quantum dots have many applications, one application for infrared quantum dots with
potential to have the most impact is for use as molecular probes for imaging, where they can
be put into biological systems and detected in tissues. Since most quantum dots emit in the
visible spectrum, only emission near the surface of the skin can be detected. Biology,
however, is fairly transparent in the infrared and therefore deeper tissues can be probed.

Mice are the standard models for most diseases and Smith explains that with quantum dots
that emit in the infrared, researchers could see almost entirely through a living rodent to see
its physiology and the locations of specific molecules throughout the body. This will allow for
better understanding of biological processes and for developing therapeutics without having
to sacrifice the mice, potentially changing preclinical drug development.
Incident description Exposed data

Andrew Smith is also an affiliate of the Holonyak Micro & Nano Technology laboratory, the
The Illinois.edu website experienced a data breach. Over 5 thousand email
Carl R. Woese Institute for Genomic Biology, the
addresses were exposed, together with credential data. Leaked records include
department
Email Password of materials science
Password hash &
password and password hash. The validity engineering, the Cancer
of the data exposed Center
couldn’t be at Illinois and the Carle Illinois College of Medicine at Illinois.
verified.
Yet we’re still informing you about a potential data breach – but keep in mind there’s
a chance of it being a false positive. Wonseok Lee is also an affiliate of the Holonyak Micro & Nano Technology laboratory at
Illinois.
No. of exposed accounts
This research was funded by the National Institutes of Health and the National Science
Foundation.
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