How Zero Knowledge Proof Powers Its System with EVM and WASM?

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How Zero Knowledge Proof Powers Its System with EVM and WASM？

How Zero Knowledge Proof Powers Its System with EVM and WASM？

Zero Knowledge Proof (ZKP) has entered early market discussions as the next crypto to explode, not because of speculation, but because its full technical stack is already live and functioning across real workloads today. The presale auction is live now, the Proof Pods are shipping, and the networks four-layer architecture is operational.

Among its most important design choices is its use of both the Ethereum Virtual Machine (EVM) and WebAssembly (WASM). This dual-runtime system is the core of how Zero Knowledge Proof supports private AI computation, encrypted data handling, and standard Web3 applications at the same time. To understand why this matters, its better to start with the basics.

Zero Knowledge Proof (ZKP) is a privacy-first blockchain designed for secure AI computation and verifiable data collaboration. It allows developers, users, and institutions to process information without ever exposing the underlying data. Using zk-SNARKs and zk-STARKs, every action on the network can be verified mathematically.

The ZKP crypto was built to solve a core problem in AI: sensitive data must often be revealed for models to run. On ZKP, computation happens directly on encrypted inputs, making AI workflows private, auditable, and safe. This design is one reason ZKP continues to appear on lists predicting the next crypto to explode.

The ZKP blockchain is also a fully self-funded project. More than $100 million has been invested before the public was invited to participate. Its Proof Pods, presale auction, and four-layer architecture are live today. This level of readiness sets it apart from typical presale or early-stage networks.

A major part of that readiness comes from ZKPs choice to use both EVM and WASM.

The Ethereum Virtual Machine makes ZKP compatible with existing Ethereum tools and smart contracts. Developers can deploy Solidity code immediately without learning new languages. This gives ZKP instant access to the global Web3 developer ecosystem, an advantage for a network considered by many as the next crypto to explode in 2025. Inside ZKP, the EVM handles tasks such as:

• dataset tokenization
• marketplace permissions
• DTK payment flows
• licensing and royalty rules
• governance actions
• data ownership records

If a hospital tokenizes encrypted medical images or if a researcher buys dataset access, these actions pass through the EVM runtime. The difference is that on ZKP, zero-knowledge proofs ensure that no private data is revealed. Developers get the same EVM workflow they already know, but with integrated privacy.

This blend of familiarity and security makes ZKP attractive and adds to why some view it as a possible next crypto to explode.

WASM brings raw computational power to ZKP. This is critical because ZKP is designed to handle advanced AI tasks, encrypted workflows, and high-speed verification.

When a Proof Pod processes an AI job, like training a model or generating a proof, the computation runs inside WASM. This runtime:

• executes AI workloads
• generates zk-proofs
• processes large encrypted datasets
• supports Substrate logic
• enables fast cryptographic operations
• handles forkless upgrades

This gives ZKP the performance needed for real compute and positions it as a contender for the next crypto to explode in the decentralized AI sector.

WASM allows ZKP to operate more like a distributed AI engine than a traditional blockchain.

Most blockchains depend on one runtime, which limits what developers can build. ZKP uses both EVM and WASM because modern compute needs two things at the same time: programmability and performance.

EVM gives ZKP full compatibility with the Ethereum ecosystem, allowing developers to deploy smart contracts, manage tokenized datasets, and run marketplace logic without changing their tools.

WASM adds the high-performance engine required for AI tasks, encrypted computation, model evaluation, and zk-proof generation. Together, they position ZKP as a strong contender for the next crypto to explode.

The real power appears when both runtimes work together through ZKPs zero-knowledge wrapper layer. A typical workflow shows how this unified system functions: an encrypted dataset is purchased through EVM smart contracts, processed by a Proof Pod using WASM, converted into a zk-proof, and then verified by EVM in milliseconds.

Rewards flow through PoI and PoSp. This combined execution model is one of the key reasons ZKP is gaining attention as a compute-first blockchain with breakout potential.

Alongside its dual EVM–WASM execution model, what truly strengthens ZKPs position as the next crypto to explode is the fact that every major part of its ecosystem is now live and functioning.

Live Presale Auction

Zero Knowledge Proof presale auction is now live. The auction uses a daily contribution model. Tokens are distributed by proportion, creating transparent pricing. Many early participants view this mechanism as a fair and predictable entry point into a network they believe could be the next crypto to explode.

Live Proof Pods

ZKP has built and manufactured $17 million worth of Proof Pods.

• Each unit cost: $249
• Global shipping
• Pods start at Level 1 and are upgradeable to Level 300
• Daily rewards scale with level and are tied to the previous days auction price

These devices perform real AI tasks, generate proofs, and validate encrypted workloads.

Live Four-Layer Architecture

ZKPs foundation includes:

• Consensus: PoI + PoSp + BABE + GRANDPA
• Security: MPC, homomorphic encryption, signatures, zk-SNARKs, zk-STARKs
• Execution: EVM + WASM
• Storage: IPFS, Filecoin, Merkle proofs

This readiness is a major reason ZKP is frequently described as a contender for the next crypto to explode in the compute category.

Zero Knowledge Proof (ZKP) combines EVM compatibility with WASM performance to support both Web3 applications and real AI computation on encrypted data. Its presale auction is live, its Proof Pods are active, and its four-layer architecture is running. ZKP does not rely on future promises; it delivers a functioning compute ecosystem from the start.

Because of this operational state and because of its dual-runtime design, ZKP continues to appear on lists predicting the next crypto to explode. For developers, researchers, and institutions, it offers a working platform where smart contracts, encrypted datasets, and AI models can run together in a verifiable, private environment.