Formation and Spectral with Nano- Study of Six and Seven Membered Ring Derivatives

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Year : 2025 | Volume : 16 | Issue : 02 | Page :
    By

    Sarah Mohammed Abed,

  1. Lecturer, Chemistry Field, Holy Karbala Education Directorate, Karbala, Karbala, Iraq

Abstract

The nanoscale properties of some organic chemicals make the materials have multiple engineering, chemical, biological and industrial applications, including heterocyclic derivatives. Advanced research in this field has made it possible to use them widely as fluorinated materials and in the electronics industry. These derivatives also have good stability at different temperatures due to the presence of heterogeneous atoms within their structure. These cyclic derivatives have proven their biological effectiveness against many types of fungi and bacteria and have given complexes similar to these systems in modern research, they have common properties in hardness and softness, as well as their pharmaceutical uses in treating many diseases such as cancer due to their antioxidant activity. Through this research, ring nanocomposites were formed that have nanoscale and biological properties. They were studied spectroscopically and through the proton and carbon resonance spectra of all derivatives, red spectral frequencies, and the nano-optical microscope.

Keywords: Nano, chemical compound, heterocyclic, six membered, oxazepane, seven membered

[This article belongs to Journal of Modern Chemistry & Chemical Technology ]

How to cite this article:
Sarah Mohammed Abed. Formation and Spectral with Nano- Study of Six and Seven Membered Ring Derivatives. Journal of Modern Chemistry & Chemical Technology. 2025; 16(02):-.
How to cite this URL:
Sarah Mohammed Abed. Formation and Spectral with Nano- Study of Six and Seven Membered Ring Derivatives. Journal of Modern Chemistry & Chemical Technology. 2025; 16(02):-. Available from: https://journals.stmjournals.com/jomcct/article=2025/view=216515


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Regular Issue Subscription Review Article
Volume 16
Issue 02
Received 15/05/2025
Accepted 23/06/2025
Published 07/07/2025
Publication Time 53 Days
48


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