TY - GEN
T1 - A Range-Based Sharding (RBS) Protocol for Scalable Enterprise Blockchain
AU - Haider, M. Z.
AU - Assuncao, M. Dias de
AU - Zhang, Kaiwen
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - Blockchain technology offers decentralization and security but struggles with scalability, particularly in enterprise settings where efficiency and controlled access are paramount. Sharding is a promising solution for private blockchains, yet existing approaches face challenges in coordinating shards, ensuring fault tolerance with limited nodes, and minimizing the high overhead of consensus mechanisms like PBFT. This paper proposes the Range-Based Sharding (RBS) Protocol, a novel sharding mechanism tailored for enterprise blockchains, implemented on Quorum. Unlike traditional sharding models such as OmniLedger and non-sharding Corda framework, RBS employs a commit-reveal scheme for secure and unbiased shard allocation, ensuring fair validator distribution while reducing cross-shard transaction delays. Our approach enhances scalability by balancing computational loads across shards, reducing consensus overhead, and improving parallel transaction execution. Experimental evaluations demonstrate that RBS achieves significantly higher throughput and lower latency compared to existing enterprise sharding frameworks, making it a viable and efficient solution for largescale blockchain deployments.
AB - Blockchain technology offers decentralization and security but struggles with scalability, particularly in enterprise settings where efficiency and controlled access are paramount. Sharding is a promising solution for private blockchains, yet existing approaches face challenges in coordinating shards, ensuring fault tolerance with limited nodes, and minimizing the high overhead of consensus mechanisms like PBFT. This paper proposes the Range-Based Sharding (RBS) Protocol, a novel sharding mechanism tailored for enterprise blockchains, implemented on Quorum. Unlike traditional sharding models such as OmniLedger and non-sharding Corda framework, RBS employs a commit-reveal scheme for secure and unbiased shard allocation, ensuring fair validator distribution while reducing cross-shard transaction delays. Our approach enhances scalability by balancing computational loads across shards, reducing consensus overhead, and improving parallel transaction execution. Experimental evaluations demonstrate that RBS achieves significantly higher throughput and lower latency compared to existing enterprise sharding frameworks, making it a viable and efficient solution for largescale blockchain deployments.
UR - https://www.scopus.com/pages/publications/105026948944
U2 - 10.1109/BCCA66705.2025.11229812
DO - 10.1109/BCCA66705.2025.11229812
M3 - Contribution to conference proceedings
AN - SCOPUS:105026948944
T3 - 2025 7th International Conference on Blockchain Computing and Applications, BCCA 2025
SP - 178
EP - 186
BT - 2025 7th International Conference on Blockchain Computing and Applications, BCCA 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 7th International Conference on Blockchain Computing and Applications, BCCA 2025
Y2 - 14 October 2025 through 17 October 2025
ER -