More efficient desalination with
crystalline carbon dots
After
9 cycles, 78% of the original efficiency was seen
“We
are trying to further improve the efficiency of the doped carbon dots,” says
Arun Chattopadhyay (right)
Researchers
at Indian Institute of Technology (IIT) Guwahati have been able to synthesise
highly crystalline carbon dots by doping them with nitrogen, sulphur and
phosphorus. The amount of phosphorus defined the extent of crystallinity.
Unlike an amorphous material, less light was scattered or reflected from
crystalline carbon dots on shining light. Instead, the crystalline material
efficiently converted the absorbed light energy into heat energy.
Simulated
sunlight
The
team led by Prof. Arun Chattopadhyay from the Department of Chemistry
successfully used the crystalline carbon dots for desalinating seawater by
exposing the carbon dots to simulated solar conditions. “The doped carbon dots
were not only able to convert light into heat energy but were also able to
interact with water and transfer the heat energy to water thus raising its
temperature,” says Prof. Chattopadhyay.
Compared
with carbon dots that were doped with all the three elements, those doped with
only nitrogen and sulphur were amorphous in nature. “When only nitrogen and
sulphur are present the polycyclic carbon does not arrange in a particular
manner, making it amorphous. But phosphate esters that form when phosphoric
acid is added bond the polycyclic fragments. That is what makes it crystalline,”
says Dr. Gayatri Natu from the Department of Chemistry, IIT Guwahati and a
coauthor of a paper published in Journal of Materials Chemistry A.
The
three- and two-element carbon dots added to water (with concentration up to 250
mg per millilitre) and exposed to simulated sunlight under reduced pressure
showed wide variability in their ability to transfer heat energy to water.
There
was 43.5% evaporation of water within 15 minutes in the case of carbon dots
doped with three elements and only 38.3% with carbon dots doped with only
nitrogen and sulphur. “When we calculated the solar thermal evaporation
efficiencies under standard atmospheric pressure, carbon dots doped with three
elements had nearly 84% efficiency. It was about 44% with carbon dots doped with
only nitrogen and sulphur,” Prof. Chattopadhyay says.
Thorough
testing
The
team tested the ability of the doped carbon dots to desalinate seawater samples
from Bay of Bengal, Persian Gulf and a sample with average sea water salinity.
Maximum desalination was achieved with carbon dots doped with three elements in
the Bay of Bengal water sample — 43% evaporation of the initial volume in 15
minutes. Only 35.5% seawater evaporated during the same time in the case of
carbon dots with two elements.
They
tested the doped carbon dots’ ability to desalinate seawater even when the salt
concentration was in excess. To do this, more seawater was added to the
residual seawater after each cycle and the desalination efficiency was tested
for nine cycles.
“The
doped carbon dots with nitrogen, sulphur and phosphorus elements retained up to
78% of the original desalination efficiency even at the end of the ninth
cycle,” says Ayan Pal from the Department of Chemistry, IIT Guwahati and first
author of the paper. “The doped carbon dots can be reused by removing excess
salt through dialysis.”
Recalling
how they stumbled upon doped carbon dots for desalination, Prof. Chattopadhyay
says: “We have been working with doped carbon dots and investigating their
properties. We found that one set of doped carbon dots was highly crystalline.
Since we were interested in the production of hydrogen from water using
sunlight we tested these crystalline carbon dots. Though it didn’t produce
hydrogen gas, it was evaporating water quickly. So we started testing it for
desalination.”
“We
are now trying to make doped carbon dots that are super crystalline so that
energy is even more efficiently converted into heat. We also trying to make a
film or sponge-like device that floats on water and evaporates water by
converting sunlight into heat,” Prof. Chattopadhyay says.
R. PRASAD
HINDU 4EB18
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