MAGNE.AI Layer1-MAGNE
Layer1 Architecture
MAGNE.AI’s blockchain - MAGNE Layer1 is built on a Proof-of-Work (PoW) consensus mechanism, prioritizing security, censorship resistance, and full decentralization. This robust design ensures that every transaction and state update is verified through permissionless computation, providing a trustless foundation resilient against Sybil attacks and Byzantine faults.
MAGNE is fully compatible with the Ethereum Virtual Machine (EVM), allowing developers to deploy existing smart contracts and use familiar tooling with minimal friction. This EVM compatibility not only accelerates onboarding but also lays the groundwork for seamless Layer2 integration and scalability.
Serving as the backbone of the MAGNE.AI ecosystem, MAGNE provides a secure and stable foundation for decentralized AI execution and real-world infrastructure coordination. It is not just a consensus layer—it’s the trust layer enabling intelligent applications at global scale.
Layer1 Token
The MHA token serves as the core utility and governance asset within MAGNE network. It is primarily used to pay for gas fees in transactions and smart contract execution, while also enabling value accrual and decentralized governance.
MHA adopts a dynamic halving model, where emissions adjust automatically based on block height and network activity. This ensures early incentives for adoption while maintaining long-term scarcity, promoting sustainable value growth. Gas fees paid in MHA are partially burned or redistributed to validators, closely aligning the token’s utility with real on-chain usage—creating a feedback loop where greater activity drives greater value.
Beyond utility, MHA empowers holders to participate in on-chain governance, enabling proposals and voting on key protocol decisions such as fee models, treasury allocation, and network upgrades. This mechanism reinforces decentralization and allows the community to shape the future of the platform.
Layer1 Innovations
MAGNE introduces architectural innovations that go beyond conventional blockchain design, targeting the specific needs of high-throughput AI applications and decentralized physical infrastructure. Key areas of improvement include optimized storage architecture and a reinforced security mechanism, both crucial for supporting scalable and secure decentralized computation.
Optimized Storage Architecture
Traditional EVM-based chains rely heavily on Merkle Trees for state integrity verification. While secure, this structure incurs significant performance overhead due to the complexity of intermediate node hashing, especially under high-frequency smart contract execution or AI state transitions.
MAGNE blockchain addresses this by introducing a lightweight state proof model that reduces reliance on Merkle intermediates without sacrificing verifiability. Combined with sharded state access and cache-layer acceleration, this approach dramatically improves read/write efficiency, lowers gas costs, and increases overall throughput. This is especially beneficial in AI-driven environments where state changes occur rapidly and frequently.
Enhanced Security Mechanism
Security is further reinforced through multi-layered validation, which augments the core PoW consensus with an active validator subset responsible for runtime verification of critical contracts and interactions. This architecture improves resistance to attack vectors such as replay, contract re-entry, and unauthorized data mutations.
The platform also employs on-chain reputation tracking and distributed key management to mitigate centralized points of failure and enhance trust recovery in hostile conditions. Future iterations will incorporate ZK-based state proofs to further enhance integrity checks and enable trust-minimized AI execution.
These innovations are modularized and exposed to developers via programmable interfaces, allowing teams to build with performance and security by default—without sacrificing flexibility or decentralization.