Flexible photocatalytic membrane based on CdS/PMMA polymeric nanocomposite films: multifunctional materials
M.I.Mohammed;
Abstract
In this study, poly(methyl methacrylate) with different doping nano-cadmium sulfide (CdS/PMMA) is prepared and characterized.
CdS/PMMA polymeric nanocomposite films were synthesized using solution casting methodology. SEM and XRD are
used for structure analysis for the studied nanocomposite films. XRD revealed the amorphous domains of PMMA polymer,
which increased with increasing CdS nanoparticle contents. SEM revealed the CdS dispersion within the PMMA matrix. CdS
nanoparticles in the PMMAmatrix are expected to be aggregated due to the casting technique. The optical energy gap is found to
be decreased after the CdS addition. ε′ and ε″ have the same behavior with the applied frequency. Maxwell-Wagner interfacial
polarization is the responsible factor for higher values of ε′–ε″ at the higher frequencies. Electrical conductivity behavior σAC
tends to obtain a constant value at lower frequencies that approach from its DC conductivity values. After doping PMMA with
nano-CdS, an exponential increase after a critical frequency value and the values of σAC was also increased. Besides, a significant
reduction in laser energy power is identified by the reduction of the output power. CdS/PMMA can attenuate the laser power due
to its nonlinear effect. CdS/PMMA nanocomposite can act as a photocatalyst to improve the performance of the
photodegradation of Rhodamine B (RhB). Among the different CdS/PMMA nanocomposite films, 3.33 wt% CdS/PMMA
demonstrates the highest efficiency in visible photocatalysis of Rhodamine B. CdS/PMMA can be utilized as multifunctional
materials use like laser optical limiting to reduce the power of laser sources and as a photocatalyst membranes.
CdS/PMMA polymeric nanocomposite films were synthesized using solution casting methodology. SEM and XRD are
used for structure analysis for the studied nanocomposite films. XRD revealed the amorphous domains of PMMA polymer,
which increased with increasing CdS nanoparticle contents. SEM revealed the CdS dispersion within the PMMA matrix. CdS
nanoparticles in the PMMAmatrix are expected to be aggregated due to the casting technique. The optical energy gap is found to
be decreased after the CdS addition. ε′ and ε″ have the same behavior with the applied frequency. Maxwell-Wagner interfacial
polarization is the responsible factor for higher values of ε′–ε″ at the higher frequencies. Electrical conductivity behavior σAC
tends to obtain a constant value at lower frequencies that approach from its DC conductivity values. After doping PMMA with
nano-CdS, an exponential increase after a critical frequency value and the values of σAC was also increased. Besides, a significant
reduction in laser energy power is identified by the reduction of the output power. CdS/PMMA can attenuate the laser power due
to its nonlinear effect. CdS/PMMA nanocomposite can act as a photocatalyst to improve the performance of the
photodegradation of Rhodamine B (RhB). Among the different CdS/PMMA nanocomposite films, 3.33 wt% CdS/PMMA
demonstrates the highest efficiency in visible photocatalysis of Rhodamine B. CdS/PMMA can be utilized as multifunctional
materials use like laser optical limiting to reduce the power of laser sources and as a photocatalyst membranes.
Other data
| Title | Flexible photocatalytic membrane based on CdS/PMMA polymeric nanocomposite films: multifunctional materials | Authors | M.I.Mohammed | Keywords | CdS/PMMA films;Membranes;Polymeric nanocomposites;Electrical conductivity;Optical filters;Visible photocatalysis | Issue Date | 2020 | Publisher | springer | Journal | Environmental Science and Pollution Research |
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