Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection
Discovering the distinctive photophysical properties of semiconductor nanomaterials has made these a popular subject in recent advances in nanotechnology-related analytical methods. Semiconductors are well-known materials that have been widely used in photovoltaic devices such as optical sensors...
Saved in:
Main Author: | |
---|---|
Format: | Thesis |
Language: | English |
Published: |
2018
|
Subjects: | |
Online Access: | http://psasir.upm.edu.my/id/eprint/83686/1/FS%202019%2026%20-%20ir.pdf http://psasir.upm.edu.my/id/eprint/83686/ |
Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
Institution: | Universiti Putra Malaysia |
Language: | English |
id |
my.upm.eprints.83686 |
---|---|
record_format |
eprints |
institution |
Universiti Putra Malaysia |
building |
UPM Library |
collection |
Institutional Repository |
continent |
Asia |
country |
Malaysia |
content_provider |
Universiti Putra Malaysia |
content_source |
UPM Institutional Repository |
url_provider |
http://psasir.upm.edu.my/ |
language |
English |
topic |
Semiconductors - Research Electrochemical analysis |
spellingShingle |
Semiconductors - Research Electrochemical analysis Ibrahim, Izwaharyanie Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection |
description |
Discovering the distinctive photophysical properties of semiconductor
nanomaterials has made these a popular subject in recent advances in
nanotechnology-related analytical methods. Semiconductors are well-known
materials that have been widely used in photovoltaic devices such as optical
sensors and bioimaging, and dye-sensitized solar cells (DSSCs), as well as for
light-emitting diodes (LEDs). The use of a narrow-bandgap semiconductor such
as cadmium sulfide nanoparticles (CdS NPs) in the photoelectrochemical (PEC)
sensor of chemicals and biological molecules plays a key role as a
photosensitizer and promotes some specific advantages in light-harvesting
media. Their size-controlled optical and electrical properties make nanomaterials
fascinating and promising materials for a variety of nanoscale photovoltaic
devices. Moreover, charge injection from the narrow bandgap to the adjacent
material leads to efficient charge separation and prolongs the electron lifetime
by the elimination of the charge carrier recombination probability. In this regard,
a single photon enables the production of multiple photogenerated charge
carriers in CdS NPs, which subsequently boosts the effectiveness of the
photovoltaic devices. In particular, this thesis highlights the recent emerging PEC
detection based on CdS NPs, specifically related to the interactions of CdS NPs
with target analytes of copper ions (Cu2+). The investigation and justification of
different CdS nanocomposites were discussed in terms of different structural
morphologies, and its impact on sensitivity and selectivity towards the targeted
Cu2+ ions. Thus, it eventually provides a significant insight in achieving real-world
applications of CdS-based PEC sensing.
In the first studies, the nanospherical-like morphology of CdS with a narrow
diameter distribution of about 350–400 nm was being employed and assembled
with a transparent ultrathin reduced graphene oxide (rGO) layer. The
nanostructured CdS adhered securely to a continuous network of rGO that also acted as an avenue to facilitate the transfer of electrons from the conduction
band (CB) of CdS. The CdS-rGO photoelectrode response for Cu2+ ion detection
had a linear range of 0.5–120 μM, with a limit of detection (LoD) of 16 nM. The
low LoD demonstrated the favourable structure of CdS-rGO as photoactive
materials in PEC sensing platform.
In the second studies, the smaller particle diameters in an average of 25−30 nm
of nanospherical CdS was obtained. The hydrothermal synthesis of CdS NPs
were decorated with gold quantum dots (Au QDs) via stepwise in situ
approaches, along with notable PEC performance. The introduction of Au which
induced a plasmonic effect on photoactive materials like CdS semiconductors
has prompted an intensive interest in PEC sensing applications. The hybrid
structure of CdS-Au resulted in the amplification of the photocurrent signal
because of the enhanced absorption of photon-generated photoelectron on the
CdS. Therefore, it contributed to a sensitive Cu2+ ions detector with the lowest
LoD of 6.73 nM in a linear range of 0.5−120 nM.
In the third studies, huge efforts have been dedicated to intensifying the PEC
performance by modifying the morphology and structure of CdS. Onedimensional
(1D) nanostructure (e.g. nanotubes, nanorods, nanofiber and
nanowire) of CdS were found to have a practical and substantial potential due to
its specific directionality for the transportation of charge carrier, thus decreasing
the probability of the recombination of charge carrier. In this regards, the 1D
nanorods (NRs) structure of CdS was prepared and the outcomes consistently
portray a much better PEC performance than the other counterpart particulate
nanostructure. A multi-functional hybrid nanostructure of CdS NRs with Au NPs
and graphene quantum dots (GQDs) has been successfully designed. The
calculated LoD was 2.27 nM in a range of 0.1-290 nM. A clear trend can be
observed based on the obtained LoD from all the three studies, and ultimately
proven that the structure, particle size and the nanocomposite materials- based
CdS could greatly influence the PEC sensing performance of Cu2+ ions.
It has been a pressing need to develop a new materials for simultaneous
detection and removal of Cu2+ ions from water sources, due to its acute and
chronic effect on human health upon exposure to excessive copper. Thus, in the
final studies, a ternary hybrid of cellulose acetate (CA) with CdS and methylene
blue (MB) in a bead composition was synthesized and investigated as a
photosensor-adsorbent of Cu2+ ions. The PEC detection of Cu2+ ions possessed
a lower LoD of 16.9 nM and a notable removal efficiency of 96.3% in the linear
range of 0.1-290 nM.
Conclusively, these research have given rise to a neoteric finding and provided
an important leap in the employment of CdS as potential semiconductor
materials in PEC sensing applications. Even though, only a few CdS-based
products that have successfully penetrated the market, but the thorough study
and investigation of CdS- based nanocomposite in this thesis can eventually disclose its real potential. Ultimately, it may become a kick-start to researchers
and innovators to come up with new CdS-based photosensor device. |
format |
Thesis |
author |
Ibrahim, Izwaharyanie |
author_facet |
Ibrahim, Izwaharyanie |
author_sort |
Ibrahim, Izwaharyanie |
title |
Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection |
title_short |
Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection |
title_full |
Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection |
title_fullStr |
Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection |
title_full_unstemmed |
Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection |
title_sort |
photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (ii) ions detection |
publishDate |
2018 |
url |
http://psasir.upm.edu.my/id/eprint/83686/1/FS%202019%2026%20-%20ir.pdf http://psasir.upm.edu.my/id/eprint/83686/ |
_version_ |
1724075402380443648 |
spelling |
my.upm.eprints.836862022-01-05T03:34:30Z http://psasir.upm.edu.my/id/eprint/83686/ Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection Ibrahim, Izwaharyanie Discovering the distinctive photophysical properties of semiconductor nanomaterials has made these a popular subject in recent advances in nanotechnology-related analytical methods. Semiconductors are well-known materials that have been widely used in photovoltaic devices such as optical sensors and bioimaging, and dye-sensitized solar cells (DSSCs), as well as for light-emitting diodes (LEDs). The use of a narrow-bandgap semiconductor such as cadmium sulfide nanoparticles (CdS NPs) in the photoelectrochemical (PEC) sensor of chemicals and biological molecules plays a key role as a photosensitizer and promotes some specific advantages in light-harvesting media. Their size-controlled optical and electrical properties make nanomaterials fascinating and promising materials for a variety of nanoscale photovoltaic devices. Moreover, charge injection from the narrow bandgap to the adjacent material leads to efficient charge separation and prolongs the electron lifetime by the elimination of the charge carrier recombination probability. In this regard, a single photon enables the production of multiple photogenerated charge carriers in CdS NPs, which subsequently boosts the effectiveness of the photovoltaic devices. In particular, this thesis highlights the recent emerging PEC detection based on CdS NPs, specifically related to the interactions of CdS NPs with target analytes of copper ions (Cu2+). The investigation and justification of different CdS nanocomposites were discussed in terms of different structural morphologies, and its impact on sensitivity and selectivity towards the targeted Cu2+ ions. Thus, it eventually provides a significant insight in achieving real-world applications of CdS-based PEC sensing. In the first studies, the nanospherical-like morphology of CdS with a narrow diameter distribution of about 350–400 nm was being employed and assembled with a transparent ultrathin reduced graphene oxide (rGO) layer. The nanostructured CdS adhered securely to a continuous network of rGO that also acted as an avenue to facilitate the transfer of electrons from the conduction band (CB) of CdS. The CdS-rGO photoelectrode response for Cu2+ ion detection had a linear range of 0.5–120 μM, with a limit of detection (LoD) of 16 nM. The low LoD demonstrated the favourable structure of CdS-rGO as photoactive materials in PEC sensing platform. In the second studies, the smaller particle diameters in an average of 25−30 nm of nanospherical CdS was obtained. The hydrothermal synthesis of CdS NPs were decorated with gold quantum dots (Au QDs) via stepwise in situ approaches, along with notable PEC performance. The introduction of Au which induced a plasmonic effect on photoactive materials like CdS semiconductors has prompted an intensive interest in PEC sensing applications. The hybrid structure of CdS-Au resulted in the amplification of the photocurrent signal because of the enhanced absorption of photon-generated photoelectron on the CdS. Therefore, it contributed to a sensitive Cu2+ ions detector with the lowest LoD of 6.73 nM in a linear range of 0.5−120 nM. In the third studies, huge efforts have been dedicated to intensifying the PEC performance by modifying the morphology and structure of CdS. Onedimensional (1D) nanostructure (e.g. nanotubes, nanorods, nanofiber and nanowire) of CdS were found to have a practical and substantial potential due to its specific directionality for the transportation of charge carrier, thus decreasing the probability of the recombination of charge carrier. In this regards, the 1D nanorods (NRs) structure of CdS was prepared and the outcomes consistently portray a much better PEC performance than the other counterpart particulate nanostructure. A multi-functional hybrid nanostructure of CdS NRs with Au NPs and graphene quantum dots (GQDs) has been successfully designed. The calculated LoD was 2.27 nM in a range of 0.1-290 nM. A clear trend can be observed based on the obtained LoD from all the three studies, and ultimately proven that the structure, particle size and the nanocomposite materials- based CdS could greatly influence the PEC sensing performance of Cu2+ ions. It has been a pressing need to develop a new materials for simultaneous detection and removal of Cu2+ ions from water sources, due to its acute and chronic effect on human health upon exposure to excessive copper. Thus, in the final studies, a ternary hybrid of cellulose acetate (CA) with CdS and methylene blue (MB) in a bead composition was synthesized and investigated as a photosensor-adsorbent of Cu2+ ions. The PEC detection of Cu2+ ions possessed a lower LoD of 16.9 nM and a notable removal efficiency of 96.3% in the linear range of 0.1-290 nM. Conclusively, these research have given rise to a neoteric finding and provided an important leap in the employment of CdS as potential semiconductor materials in PEC sensing applications. Even though, only a few CdS-based products that have successfully penetrated the market, but the thorough study and investigation of CdS- based nanocomposite in this thesis can eventually disclose its real potential. Ultimately, it may become a kick-start to researchers and innovators to come up with new CdS-based photosensor device. 2018-11 Thesis NonPeerReviewed text en http://psasir.upm.edu.my/id/eprint/83686/1/FS%202019%2026%20-%20ir.pdf Ibrahim, Izwaharyanie (2018) Photoelectrochemical sensor based on modified cadmium sulfide nanomaterials for copper (II) ions detection. Doctoral thesis, Universiti Putra Malaysia. Semiconductors - Research Electrochemical analysis |