Your search keyword '"Zinc sulfide"' showing total 2 results

1. Researchers from Indian Institute of Technology (IIT) Jodhpur Report New Studies and Findings in the Area of Nanomaterials (Synergistic Nanomaterials: Zinc Sulfide-polyaniline for Ciprofloxacin Electrochemical Sensing).

Subjects

RESEARCH personnel, NANOSTRUCTURED materials, CIPROFLOXACIN, TECHNICAL institutes, ZINC

Abstract

A recent report from the Indian Institute of Technology (IIT) Jodhpur discusses the use of zinc sulfide-polyaniline nanocomposites for the electrochemical sensing of the antibiotic ciprofloxacin (CIP). The researchers aimed to develop a reliable technique for detecting CIP in order to monitor its concentrations and protect public health. The nanocomposite-modified electrodes exhibited improved electrochemical activity and selectivity for CIP, with a linear detection range of 50 to 0.75 μM and a limit of detection of 0.5 μM. This research provides valuable insights into the application of nanomaterials in the field of electrochemical sensing. [Extracted from the article]

Published

2023

2. The possibility of a ZnS-bearing sulfide melt at 600°C: Evidence from the Rajpura–Dariba deposit, India, supported by laboratory melting experiment.

Author

Pruseth, Kamal Lochan, Jehan, Neshat, Sahu, Pratibha, and Mishra, Biswajit

Subjects

*ZINC sulfide, *SEDIMENTATION & deposition, *MELTING, *PYRITES, *SPHALERITE

Abstract

Abstract: Inclusions of euhedral pyrite crystals are seen within sphalerite occupying veins and fractures in the Rajpura–Dariba Zn–Pb–Cu sulfide deposit in Rajasthan, India. Sphalerite in the deposit shows wide variation in composition and contains high sulfur, with Fe/(S–Zn) varying from 0.49 to 1.06, indicating that a portion of the Fe in sphalerite could be expressed as a pyrite (FeS2) component and that the pyrite inclusions within sphalerite in the vein ore could have formed due to exsolution. We have conducted experiments by the evacuated silica tube method at 600°C, pertinent to the peak metamorphic conditions of the Rajpura–Dariba deposit. Our experiments were aimed at exploring the possibility of a ZnS-bearing sulfide partial melt that could precipitate sufficiently S-rich sphalerite, which in turn might exsolve pyrite. The starting mixture comprised synthetic FeS, ZnS, PbS, Cu2S and S in the molar proportions of 40, 33, 9, 9 and 9%, respectively, which approximately corresponded to molar proportions of 27% FeS, 40% ZnS, 11% PbS and 22% CuFeS2. Electron probe micro analysis (EPMA) of the resulting run product showed the presence of a Cu–Fe–Zn–Pb–S melt containing 4.61mol% ZnS. In the coexisting sphalerite the estimated FeS2 component was 9.07mol%. The eutectic temperature was determined to be 595°C with a melt containing 22.44mol% FeS, 31.24mol% Cu2S, 5.37mol% ZnS, 35.81mol% PbS and 5.14mol% FeS2. The sphalerite that was in equilibrium with the eutectic melt contained 6.72mol% FeS2. Our experimental results suggest that a ZnS-bearing sulfide melt containing as high as 5mol% ZnS was produced during metamorphism at Rajpura–Dariba by partial melting of the preexisting ore. Further experiments confirmed that a minimum sulfur fugacity of −2.46 log units is required for initiating melting. Pyrite and sphalerite (containing Fe and stoichiometrically excess S) are the solidus phases present in all melt-bearing experimental run products except one with much higher ZnS, suggesting that these two minerals at Rajpura–Dariba could have simultaneously crystallized from a sulfide partial melt giving rise to the observed poikilitic textural relation between the two. [Copyright &y& Elsevier]

Published

2014