CONVERGENT TRUST FRAMEWORKS: INTEGRATING AI-DRIVEN REAL-TIME FRAUD DETECTION WITH BLOCKCHAIN-BASED IDENTITY AND PROVENANCE FOR RESILIENT DIGITAL BANKING

Authors

  • Dr. Mateo Sinclair Department of Computer Science, University of Toronto, Canada Author

Keywords:

AI fraud detection, blockchain identity, real-time streams

Abstract

This article develops a comprehensive theoretical and practical synthesis on integrating artificial intelligence (AI)–based real-time fraud detection with blockchain-enabled identity, access control, and provenance mechanisms for modern digital banking ecosystems. The work draws on a curated set of contemporary studies spanning stream-processing fraud detection, blockchain architectures for identity and data integrity, biometric and multifactor authentication practices, and the socio-technical governance necessary for trustworthy financial services (Hebbar, 2025; Liao et al., 2022; Nguyen et al., 2020; Ravi, 2021). The paper articulates a Convergent Trust Framework (CTF) that reconciles operational requirements—low-latency detection, explainability, privacy preservation, and regulatory compliance—with cryptographic and ledger design choices—permissioned ledgers, off-chain commitments, and selective disclosure strategies (Hassani et al., 2018; Ahmad et al., 2024). Methodologically, the article synthesizes thematic evidence, performs rigorous conceptual integration, and derives design propositions and implementation pathways for practitioners while mapping a research agenda to address empirical gaps. Findings highlight that stream-processing AI systems (e.g., Kafka-based architectures) can achieve near-real-time detection but must be coupled with tiered explainability and adaptive retraining to reduce false positives and model drift (Hebbar, 2025; Grammatikos & Papanikolaou, 2021). Blockchain layers offer tamper-evident anchors for forensic artifacts and identity claims, yet throughput, privacy, and governance constraints necessitate hybrid on-chain/off-chain designs and permissioned consortium models for banking contexts (Liao et al., 2022; Uriawan et al., 2025). The framework emphasizes human-in-the-loop governance, policy-driven smart contracts, and privacy-preserving cryptographic commitments as essential for operationalizing trust. Limitations of current research—scarcity of large-scale field deployments and empirical adversarial evaluations—are delineated, and a multi-year empirical program combining pilot deployments, red-team exercises, and regulatory impact studies is proposed. This integrated perspective aims to move research and practice beyond isolated technological silos toward resilient, auditable, and user-centered financial infrastructures.

Downloads

Download data is not yet available.

References

Wewege, L., Lee, J., & Thomsett, M. C. (2020). Disruptions and digital banking trends. Journal of Applied Finance and Banking, 10(6), 15-56.

Nguyen, D. C., Pathirana, P. N., Ding, M., & Seneviratne, A. (2020). Integration of blockchain and cloud of things: Architecture, applications and challenges. IEEE Communications Surveys & Tutorials, 22(4), 2521-2549.

Ravi, H. (2021). Innovation in banking: fusion of artificial intelligence and blockchain. Asia Pacific Journal of Innovation and Entrepreneurship, 15(1), 51-61.

Hassani, H., Huang, X., & Silva, E. (2018). Banking with blockchain-ed big data. Journal of Management Analytics, 5(4), 256-275.

Khatwani, R., Mishra, M., Bedarkar, M., Nair, K., & Mistry, J. (2023). Impact of blockchain on financial technology innovation in the banking, financial services and insurance (BFSI) sector. Journal of Statistics Applications and Probability, 12(1), 181-189.

Addula, S. R., Meduri, K., Nadella, G. S., & Gonaygunta, H. (2024). AI and Blockchain in Finance: Opportunities and Challenges for the Banking Sector. International Journal of Advanced Research in Computer and Communication Engineering, 13(2), 184-190.

Knezevic, D. (2018). Impact of blockchain technology platform in changing the financial sector and other industries. Montenegrin Journal of Economics, 14(1), 109-120.

Komandla, V., & Perumalla, S. (2017). Transforming traditional banking: Strategies, challenges, and the impact of fintech innovations. Educational Research (IJMCER), 1(6), 01-09.

Shrier, D., Wu, W., & Pentland, A. (2016). Blockchain & infrastructure (identity, data security). Massachusetts Institute of Technology-Connection Science, 1(3), 1-19.

Karaszewski, R., Modrzyński, P., & Modrzyńska, J. (2021). The use of blockchain technology in public sector entities management: An example of security and energy efficiency in cloud computing data processing. Energies, 14(7), 1873.

Choithani, T., Chowdhury, A., Patel, S., Patel, P., Patel, D., & Shah, M. (2024). A comprehensive study of artificial intelligence and cybersecurity on bitcoin, crypto currency and banking system. Annals of Data Science, 11(1), 103-135.

Hebbar, K. S. (2025). AI-DRIVEN REAL-TIME FRAUD DETECTION USING KAFKA STREAMS IN FINTECH. International Journal of Applied Mathematics, 38(6s), 770-782.

Agidi, R. C. (2018). Biometrics: The future of banking and financial service industry in Nigeria. International Journal of Electronics and Informatics Engineering, 9(2), 91-105.

Venkatraman, S., & Delpachitra, I. (2008). Biometrics in banking security: A case study. Information Management & Computer Security, 16(4), 415-430.

Barclays Corporate and Investment Bank. (2020). 2fac authentication world. https://2facauthentication.com/?p=488

Electronic Frontier Foundation (EFF). (2016). How to enable two-factor authentication on Bank of America. https://www.eff.org/deeplinks/2016/12/how-enable-two-factor-authentication-bank-america

Hongkong and Shanghai Banking Corporation (HSBC). (2018). Online security. https://www.business.hsbc.com.tw/en-gb/tw/generic/security

Royal Bank of Canada (RBC). (2021). Security feature: Two factor authentication. https://www.rbcroyalbank.com/caribbean/digital-hub/security-two-factor.html

Ali, G., Dida, M. A., & Sam, A. E. (2020). Two-factor authentication scheme for mobile money: a review of threat models and countermeasures. Future Internet, 12(10), 1-27.

Dmitrienko, A., Liebchen, C., Rossow, C., & Sadeghi, A. R. (2014). Security analysis of mobile two-factor authentication schemes. Intel Technology Journal, 18(4), 138-161.

Nath, A., & Mondal, T. (2016). Issues and challenges in two factor authentication algorithms. International Journal of Latest Trends in Engineering and Technology, 6(3), 318-327.

Capital One. (2018). Bank securely. https://www.capitalone.com/digital/identity-protection/

Chase Bank. (2021). How we protect you. https://www.chase.com/digital/resources/privacy-security/security/how-we-protect-you

Citibank. (2019). About Citi identification code text message. https://online.citi.com/US/JRS/pands/detail.do?ID=CitiMFA

Woodforest National Bank. (2021). Privacy & security. https://www.woodforest.com/Personal/Services/Online-Banking/Online-Banking-Security

Mukhtar, M. (2015). Perceptions of UK based customers toward Internet banking in the United Kingdom. Journal of Internet Banking & Commerce, 20(1), 1-38.

Nayanajith, D. A. G., Weerasiri, R. A. S., & Damunupola, A. (2019). A review on e-banking adoption in the context of e-service quality. Sri Lanka Journal of Marketing, 5(2), 25-52.

Ozili, P. K. (2018). Impact of digital finance on financial inclusion and stability. Borsa Istanbul Review, 18(4), 329-340.

Tropina, T. (2016). Do digital technologies facilitate illicit financial flows? In World Bank. Digital Dividends (World Development Report 2016).

Uriawan, W., Pratama, A. P., & Mursyid, S. (2025). Blockchain technology for optimizing security and privacy in distributed systems. Computer Science and Information Technologies, 6(2), 214-224.

Verma, A. (2025). Blockchain for Cyber Security: Enhancing Data Integrity and Trust in Digital Transactions.

Bakare, S. (2015). Varying impacts of electronic banking on the banking industry. Journal of Internet Banking and Commerce, 20(2), 1-9.

Grammatikos, T., & Papanikolaou, N. I. (2021). Applying Benford’s Law to detect accounting data manipulation in the banking industry. Journal of Financial Services Research, 59, 115-142.

Bhagwat, G. (2025). Blockchain for Secure Big Data Transactions. The Voice of Creative Research, 7(2), 289-294.

Kaliagurumoorthi, K., Nadh, V. S., Arputharaj, B. S., Ramya, M., & Deepthi, T. (2025). Enhancing Trust and Security in Digital Ecosystems With Blockchain Technology: Implications for Economics and Finance. In 2025 International Conference on Technology Enabled Economic Changes (InTech), IEEE.

Natrayan, L., Kaliappan, S., Bhaskarani, N., & Kasireddy, L. C. (2025). Enhancing Trust and Security in Digital Ecosystems with Blockchain Technology. In 2025 International Conference on Technology Enabled Economic Changes (InTech), IEEE.

Choithani, T., Chowdhury, A., Patel, S., Patel, P., Patel, D., & Shah, M. (2024). A comprehensive study of artificial intelligence and cybersecurity on bitcoin, crypto currency and banking system. Annals of Data Science, 11(1), 103-135.

Downloads

Published

2025-11-30

Issue

Vol. 12 No. 11 (2025): Volume 12 Issue 11 2025

Section

Articles

License

Copyright (c) 2025 Dr. Mateo Sinclair (Author)

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

How to Cite

CONVERGENT TRUST FRAMEWORKS: INTEGRATING AI-DRIVEN REAL-TIME FRAUD DETECTION WITH BLOCKCHAIN-BASED IDENTITY AND PROVENANCE FOR RESILIENT DIGITAL BANKING . (2025). EuroLexis Research Index of International Multidisciplinary Journal for Research & Development, 12(11), 765-773. https://researchcitations.org/index.php/elriijmrd/article/view/34

Similar Articles

41-50 of 70

You may also start an advanced similarity search for this article.