School Of Basic And Applied Sciences

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Subject: search.filters.subject.Charge transfer

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    Synergistic photophysical and electrochemical response of Te @ PANI for energy harvesting
    (Springer, 2023-01-07T00:00:00) Rani, Pinki; Jewariya, Yogesh; Haldar, Krishna Kanta; Biswas, Rathindranath; Alegaonkar, Prashant S.
    Materials with synergistic functionality are of great importance in consumer electronics. We report on the preparation and assessments of Te @ PANI composite for energy conversion and storage application. Initially, (5�15%) Te @ PANI composites were synthesized by the facile, room temperature, time and cost-effective solid-state synthesis technique followed by characterizations using Fourier transform infra-red, UV-Visible, energy dispersive spectroscopic including X-ray diffractometry and field electron scanning microscopy. Te exfoliates polymeric segments of PANI by bonding benzenoid rings through sulphonated impurity sites which have a profound impact on symmetry molecular bond vibrations. Its analysis is presented. In photophysical application, both dark and luminescent I-V measurements have been performed that showed a linear variation with minimum photo-resistance offered by 10% composite and reaching current > 10�mA under 1.5�V biased conditions. In storage response, Te @ PANI supercapacitor devices are dominating in inductive coupling over capacitive coupling by ten times. Corresponding shunt impedance is seen to be favourably lower for 10% composition, and respective charge transfer impedance has also followed identical behaviour over other classes of samples. The quality factor of the device for 10% is found to be almost twelve times better. However, at a low scan rate (10�mV/s), the presence of Te has changed the tendency of ion migration, thereby, reducing the magnitude of ion current by about three times with an increase in Te from 5 to 15%. Thus, fabricated composite demonstrated synergistic aspects of energy. � 2023, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.
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    Photophysical properties of push-pull 8-aryl-deoxyguanosine probes within duplex and G-quadruplex structures
    (Royal Society of Chemistry, 2016) Blanchard, D.J.M.; Fadock, K.L.; Sproviero, M.; Deore, P.S.; Cservenyi, T.Z.; Manderville, R.A.; Sharma, P.; Wetmore, S.D.
    In this study, we outline the structural and photophysical properties of donor-acceptor (D-A) 8-aryl-2?-deoxyguanosine (8aryldG) probes within duplex and G-quadruplex (GQ) structures produced by the thrombin binding aptamer (TBA, 5?-GGTTG5G6TG8TGGTTGG). The probes vary in 8-aryl ring size, degree of twist angle between the aryl ring and nucleobase component, degree of acceptor character, and nature of visibly emissive charge transfer (CT) states. Probes with the aryl ring directly attached to the nucleobase favor the syn-conformation and strongly destabilize the duplex structure, as measured by UV thermal melting experiments. However, these probes can stabilize the antiparallel GQ produced by TBA when inserted into the G-tetrad at the syn-G5 position, and strongly decrease GQ stability when inserted at the anti-G6 position. Nucleoside probes with the aryl ring separated from the nucleobase by a vinyl linker favor the anti-conformation. Furthermore, the nature of the aryl group dictates an ability of these probes to be accomodated within the GQ at the anti-G6 position. 8AryldG probes that favor planar CT states (CTP) exhibit bright emission in both duplex and GQ structures, but lack fluorescence sensitivity to changes in the microenvironment. In contrast, probes that afford twisted CT states (CTT) exhibit weak fluorescence in duplex and GQ structures in water, but display fluorescence signalling capability for monitoring GQ formation in a crowded environment. ? The Royal Society of Chemistry 2016.
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    Identifying the preferred interaction mode of naringin with gold nanoparticles through experimental, DFT and TDDFT techniques: Insights into their sensing and biological applications
    (Royal Society of Chemistry, 2016) Singh, Baljinder; Rani, Monika; Singh, Janpreet; Moudgil, Lovika; Sharma, Prateek; Kumar, Sanjeev; Saini, G.S.S.; Tripathi, S.K.; Singh, Gurinder; Kaura, Aman
    In this work, the binding behaviour of naringin-a flavonoid with AuNPs is explained by combining experimental and theoretical approaches. We have systematically analysed the effect of temperature and concentration of naringin and gold (Au) in the formation of naringin stabilized Au nanoparticles (N-AuNPs). The interaction of naringin with gold nanoparticles (AuNPs) is investigated by various techniques such as UV-visible spectroscopy, TEM, FT-IR, XRD and gel electrophoresis. These studies indicate that naringin acts as a reducing and stabilizing agent. Further, we have modelled the two side chains of naringin with the functional groups [C10H7O2] and [C6H5O]-, and identified the lowest energy configurations of these groups with AuNPs with the help of density functional theory (DFT). The [C10H7O2]-Au13 has higher binding energy than [C6H5O]--Au13 and it is attributed to delocalized molecular orbitals in [C10H7O2], hence higher charge transfer to the Au13 cluster. On the basis of the resulting structures, we examine the optical properties using time-dependent density functional theory (TDDFT). We observe significant changes in the optical spectra of the representative structures of side chains with the AuNPs. The peak in the spectra of the Vis region of [C10H7O2]-Au13 undergoes a shift towards lower wavelength in comparison to [C6H5O]--Au13. Natural transition orbitals (NTOs) of hole and particle states of the [C10H7O2]-Au13 conjugate system are localized on [C10H7O2] and Au13, respectively, whereas for the [C6H5O]--Au13 both hole and particle states are localized on the Au13 cluster. These N-AuNPs show their applicability as a sensor for detecting aluminium ions (Al3+) in aqueous solution. These NPs are also found to be biocompatible with normal red blood cells and MDAMB-231 breast carcinoma cell lines, as evaluated from hemolysis and cytotoxicity assays. Thus, naringin offers non-toxic and bio friendly N-AuNPs, which are considered to be the best vehicle for drug release and other possible biomedical and sensing applications. ? 2016 The Royal Society of Chemistry.