Cloud-Native Architectures for Scalable Enterprise Applications

  • Authors

    • Kanya Mohammed Department of Computer Science, Prince of Songkla University, Thailand. Author
    • Dr. Naree Thongchai Department of Computer Science, Prince of Songkla University, Thailand. Author

    Published 2026-01-08

  • Cloud-Native Architecture, Microservices, Kubernetes, DevOps, Scalability, Containerization, Enterprise Applications, Service Mesh, CI/CD, Elasticity

    Issue

    Vol. 1 No. 1 (2026)

    Section

    Articles

    How to Cite

    [1]
    K. Mohammed and N. Thongchai, “Cloud-Native Architectures for Scalable Enterprise Applications”, ijmiet, vol. 1, no. 1, pp. 52–65, Jan. 2026, Accessed: Mar. 02, 2026. [Online]. Available: https://worldcometresearchgroup.com/index.php/ijmiet/article/view/80

  • Abstract

    Cloud-native architecture has been the new paradigm in enterprise application development that facilitates organization to reach unprecedented levels of scalability, agility, reliability, and operational efficiency. The dynamic business requirements, short delivery cycles of software solutions and the necessity of globally distributed services are mounting an increasing challenge on traditional monolithic systems. The concepts of microservices architecture, containerization, DevOps culture, and continuous delivery pipelines are the main principles in cloud-native systems that circumvent the limitations. This paper will be a detailed study of cloud-native architecture and its strategic role in a digital transformation process of businesses. Scalability models, distributed resource management, service orchestration, elasticity patterns and resilience techniques applied by cloud-native platforms are further detailed in the abstract. We address the transformation of enterprise application infrastructure out of on-premise legacy resource setting into service-based cloud environments properly configured to scale horizontally. The paper also investigates that the container orchestration systems such as Kubernetes make deployment, scaling, and failover operations to be declaratively automated. The purpose of service mesh, API-oriented architecture, event-based systems, policy-oriented autoscaling, and infrastructure-as-code (IaC) are examined to show how the architectural resilience and operational administration are accomplished. An approach to assess the maturity of cloud-native systems is presented based on the performance benchmarking, lifecycle automation, security compliance, and cost optimization indicators as part of a methodological framework. Also, the paper presents experimental evaluations of the response time, throughput, service resiliency, and infrastructure utilization in both traditional and cloud-native deployments. Findings indicate the application availability, frequency of deployment and scalability efficiency are very high. Lastly, such challenges as state management, data consistency, complexities in migrating, observability, and operational complexity are also addressed. The innovations that are emphasized by the best practices and future-oriented thinking include serverlesscomputing, auto-scaling that is run with AI, workloads based on WebAssembly, and automated cloud operations. All in all, the paper points to the idea that cloud-native architectures are not something the enterprises can afford to ignore on their quest towards maintaining competitive viability in the rapidly changing digital economy.

  • References

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