Top Zero Knowledge Proofs tokens by market capitalization
Zero Knowledge Proofs contains 59 coins with a total market capitalization of $13.28B and an average price change of -0.62%. They are listed in size by market capitalization.
Zero Knowledge Proofs (ZKPs) are a cryptographic technique allowing one party (the prover) to demonstrate to another party (the verifier) that they possess specific information without revealing the actual data. Essential in the realm of blockchain and privacy-centric cryptocurrencies, ZKPs ensure transaction validation without disclosing transaction details such as sender, receiver, or amount. For instance, zk-SNARKs and zk-STARKs, used in cryptocurrencies like Zcash, facilitate these private verifications.
See more
Name | Price | 24h (%) | 7D (%) | Market cap | 24h volume | Supply | Last 24h | Operation | |
---|---|---|---|---|---|---|---|---|---|
$0.07646 | +1.35% | -48.05% | $0 | $400,364.97 | 0.00 | ||||
LayerAILAI | $0.01154 | -1.97% | -25.79% | $0 | $3.13M | 0.00 | Trade | ||
WhirlWHIRL | $0.009970 | -0.61% | -56.01% | $0 | $0 | 0.00 | |||
MazzeMAZZE | $0.002417 | -6.46% | -33.92% | $0 | $61,283.46 | 0.00 | |||
EdgeSwapEGS | $0.0004823 | +1.85% | -19.19% | $0 | $210.18 | 0.00 | |||
SatoshiVMSAVM | $0.6292 | +1.70% | -21.63% | $0 | $97,089.71 | 0.00 | |||
$0.01784 | -5.29% | -21.85% | $0 | $363.75 | 0.00 | ||||
ZigZagZZ | $0.003426 | +7.52% | -5.05% | $0 | $86,095.66 | 0.00 | Trade | ||
$0.02206 | +2.89% | -20.89% | $0 | $1,866.01 | 0.00 |
FAQ
How do Zero-Knowledge Proofs (ZKPs) work?
Zero-Knowledge Proofs (ZKPs) are cryptographic methods that allow one party to prove the truth of a statement to another without revealing any specific details about the statement itself. At its core, a ZKP involves a prover making a commitment to a piece of information. The verifier then challenges the prover to validate their claim without revealing the information. Through a series of responses and verifications, the verifier becomes convinced of the statement's validity without gaining knowledge of the statement's content. This ensures privacy and security in processes like transactions and identity verifications.
What are the different types of Zero Knowledge Proofs?
Zero Knowledge Proofs (ZKPs) can be categorized into various types based on their properties and use cases: - zk-SNARKs (Zero-Knowledge Succinct Non-Interactive Argument of Knowledge): These proofs are succinct, meaning they can be quickly verified, and they're non-interactive, so no back-and-forth communication is required between the prover and verifier. They're notably used in the Zcash cryptocurrency. - zk-STARKs (Zero Knowledge Scalable Transparent Argument of Knowledge): These are similar to zk-SNARKs but do not rely on a trusted setup, which means they're more transparent. They also offer better scalability but can be more complex and computationally intensive. - Bulletproofs: These are short non-interactive ZKPs without trusted setup. They are especially useful for range proofs, ensuring that a secret number is within known bounds. - zk-ROLLUPs: Used in the context of blockchain scaling, zk-ROLLUPs bundle multiple transactions into a single proof that can be verified on-chain, saving space and computation.
Why are Zero Knowledge Proofs (ZKPs) important in blockchain and cryptocurrency?
Zero Knowledge Proofs (ZKPs) are important in blockchain and cryptocurrency for maintaining user privacy. They enable transactions to be verified as legitimate without revealing transaction specifics like sender, receiver, or amount, thereby balancing transparency with user confidentiality.
Are Zero Knowledge Proofs (ZKPs) only used in cryptocurrency?
No, while Zero Knowledge Proofs (ZKPs) have become particularly popular in the blockchain and cryptocurrency realm, they have potential applications in many other areas, such as secure authentication, privacy-preserving data sharing, and confidential voting systems.
What are the challenges associated with implementing Zero Knowledge Proofs (ZKPs)?
Implementing Zero Knowledge Proofs (ZKPs) can be computationally intensive, making real-time applications challenging. Moreover, building efficient and secure ZKP systems requires deep cryptographic expertise. There's also the challenge of interoperability – ensuring that ZKP systems work smoothly with existing systems and standards.
How do Zero Knowledge Proofs (ZKPs) ensure both privacy and verification at the same time?
Zero Knowledge Proofs (ZKPs) work on the principle that it's possible to prove knowledge of certain information without revealing that information. Through intricate cryptographic techniques, a prover can convince a verifier of the validity of a statement without exposing the underlying data, thus achieving verification while preserving privacy.
What's the difference between "interactive" and "non-interactive" Zero Knowledge Proofs (ZKPs)?
In interactive ZKPs, the prover and verifier engage in back-and-forth communication for the proof to be established. In non-interactive ZKPs, the prover can send a single message to the verifier, who can then ascertain the truth of the statement without any further interaction. Non-interactive ZKPs are often preferred for scalability and efficiency in many applications.
How do Zero Knowledge Proofs (ZKPs) enhance security in decentralized systems?
In decentralized systems, transparency is crucial, but so is privacy. ZKPs bridge this gap. They allow nodes or participants to validate transactions and data without exposing sensitive details, making it possible to maintain a secure, transparent ledger without compromising user or transaction confidentiality.