IJSRET Volume 2 Issue 4, July-2016

Container Intelligence At Scale: Harmonizing Kubernetes, Helm, And OpenShift For Enterprise Resilience

Authors: Harish Govinda Gowda

Abstract: Containers have become the backbone of modern enterprise IT, providing portability, agility, and consistency across environments. However, scaling containers across hybrid and multi-cloud infrastructures requires more than orchestration—it demands governance, security, and resilience. This article explores how Kubernetes, Helm, and OpenShift can be harmonized to achieve container intelligence at scale. Kubernetes provides orchestration, Helm simplifies application deployment and lifecycle management, and OpenShift delivers governance, compliance, and enterprise-grade security. By layering these tools together, organizations can create resilient, scalable ecosystems that balance agility with trust. The discussion highlights key challenges in scaling containers, the role of each tool, and best practices for enterprise adoption, emphasizing that true resilience comes from harmonizing orchestration, management, and governance into one cohesive framework.

DOI: http://doi.org/10.5281/zenodo.16992539

Development Of Functionalized Schiff Base Derivatives And Their Role In Advanced Organic And Medicinal Chemistry

Authors: Janaki Ramarao Kasa, Dr. Chitra Gupta

Abstract: Due to their straightforwardness in synthesis, controllable electronic properties, high coordination abilities, and extensive biological importance, Schiff base derivatives concentrate greater importance and expertise in the research of organic and medicinal chemistry. The present study article surveys literature up to January 2016 so as to examine the impact of trends in functionalization on the chemical behaviour and medical uses of Schiff base antecedents. The research design used in the study is structured secondary research with the 60 peer-reviewed references published up to the beginning of the year 2016. The coding of these articles was by year of publication, structural classification, functional group modification, the ability to form metal-complex, biological use, and profile of activity reported. This was to identify the dominant research themes, gauge the major research treatment and interpretive uses, and to determine whether structural functionalization and metal coordination accepted superior performance. It has been disclosed that since 2010 and 2015, there was an increase in the number of studies published on Schiff bases, along with the most widespread types of use in the field were antimicrobial, anticancer, antioxidant, enzyme inhibitory, and chemosensing purposes. Schiff bases based on heteroaryl, quinoline, quinazoline, isatin, triazole and coumarin were particularly noticeable. Metal-complexed Schiff bases were found to be more commonly linked with DNA interaction, cytotoxicity and redox-based activity whereas metal free versions were more common in antimicrobial and enzyme-inhibition studies. Electron-withdrawing groups, incorporation of heterocyclic rings and the use of donor atoms like nitrogen and oxygen were always used to enhance reactivity and biological potential. The paper concludes that functionalized Schiff base derivatives were widely used as molecular platforms with twist before 2016 in selecting synthetic organic chemistry and coordination chemistry and medicinal chemistry, and the development of multifunctional therapeutics, molecular probes and catalytic systems used after 2016 builds off their earlier development.

Atmospheric Chemistry Of Greenhouse Gases And Their Role In Global Warming

Authors: Dr. Sarika Sharma

Abstract: Atmospheric chemistry plays an important role in the global climate system as greenhouse gases (GHGs) are involved in the Earth's climate system, radiation, and atmosphere. GHGs such as carbon dioxide (CO₂), methane (CH₄), nitrous oxide (N₂O), and halogenated compounds absorb infrared light and emit it in the atmosphere of Earth as greenhouse gases, and this is associated with the greenhouse effect. The heat in the lower atmosphere is retained, and global warming and the surface temperature of the Earth are increasing. As such, the chemistry of greenhouse gases depends on the concentration of atmospheric gases as well as their chemical composition, reactivity, lifetime, and interaction with solar and terrestrial radiation (e.g., photochemical reactions, oxidation processes, gas-aerosol interaction). For example, methane oxidation and nitrogen oxide cycles play an important role in ozone production and secondary radiative forcing, so that the chemistry of atmospheric chemistry and climate are interrelated. Since the 20th century, anthropogenic activities such as combustion of fossil fuels, industrial pollution, deforestation, and agricultural processes have increased the GHG levels in our atmosphere, thus adding to the natural greenhouse effect. However, CO₂ is the most important greenhouse gas present now, but it is not the only one that is responsible for warming, and other gases such as CH₄ and N₂O are essential in the global warming process as well. Atmospheric chemistry reveals that the greenhouse effect is not only dependent on CO₂, but many interacting gases are involved in the climate processes. Recent studies have also shown that changes in the composition of the atmosphere can lead to severe weather events, radiative forcing, and climate feedback loops, and the consequences can be dramatic for global warming. In any system for climate change, the interplay of greenhouse gases, aerosols, and chemical reactions in the atmosphere should be taken into account. From a global perspective, understanding the chemistry and nature of greenhouse gases is necessary to understand what is driving us toward global warming. The chemical properties and interactions of these gases are also useful in understanding how climate change must be countered in the long run and how to identify solutions to this problem for climate policy.

DOI: https://doi.org/10.5281/zenodo.19416017