Overview
Cross-Chain Transfer Protocol (CCTP) is a permissionless onchain utility that facilitates USDC transfers securely between supported blockchains via native burning and minting. Circle created CCTP to improve capital efficiency and minimize trust assumptions when using USDC across blockchains. CCTP enables developers to build multichain applications that allow users to perform 1:1 transfers of USDC securely across blockchains.Tip: Use Bridge Kit for easy crosschain transfers through CCTP.Bridge Kit is an SDK that uses CCTP as its protocol provider to let you transfer USDC between blockchains in just a few lines of code
Note: CCTP V2 uses a separate set of contracts and is not backward
compatible with earlier versions. Developers who need to continue using
Standard Transfer should consider upgrading to the latest CCTP version.
Background and Design
The following sections provide additional context on CCTP’s evolution, the challenges it addresses, and its architectural principles. Expand any to explore these deeper technical details.Differences between CCTP V2 and CCTP V1
Differences between CCTP V2 and CCTP V1
To better understand the evolution of CCTP, the following table highlights the
key differences between CCTP V2 and CCTP V1:
| Feature | CCTP V2 | CCTP V1 |
|---|---|---|
| Finality Time | Fast Transfer: faster-than-finality, ~8-20 seconds for EVM chains Standard Transfer: , ~13-19 minutes for Ethereum and L2 chains | Standard Transfer: hard finality, ~15 to 19 minutes for Ethereum and L2 chains |
| Supported Blockchains | Standard Transfer: Arbitrum, Avalanche, Base, Codex, Ethereum, HyperEVM, Ink, Linea, OP Mainnet, Plume, Polygon PoS, Sei, Solana, Sonic, Unichain, World Chain, XDC Fast Transfer: Arbitrum, Avalanche*, Base, Codex, Ethereum, HyperEVM*, Ink, Linea, OP Mainnet, Plume, Polygon PoS*, Sei*, Solana, Sonic*, Unichain, World Chain, XDC* (*) Destination chains only | Standard Transfer: Aptos, Arbitrum, Avalanche, Base, Ethereum, Noble, OP Mainnet, Polygon PoS, Solana, Sui, Unichain |
| Pricing | Standard Transfer: onchain fee (0) Fast Transfer: onchain fee (per chain) | Standard Transfer: No fee |
| User Experience | Advanced cross-chain functionality, optimized for speed and composability | Standard cross-chain functionality |
| Liquidity | Enables native USDC transfers post and/or hard finality via a burn and mint method | Enables native USDC transfers post hard finality via a burn and mint method |
| Backward Compatibility | Not backward compatible; forms a distinct network | N/A |
Understanding the Problem
Understanding the Problem
Blockchains often operate in siloed environments and cannot natively communicate
with one another. While some ecosystems, such as Cosmos, use built-in protocols
like the Inter-Blockchain Communication (IBC) protocol to enable data
transmission between their appchains, direct communication between isolated
networks, such as Ethereum and Avalanche, remains infeasible.Traditional bridges exist to address this limitation by enabling the transfer of
digital assets, such as USDC, across blockchains. However, these bridges come
with significant drawbacks. Two common methods, lock-and-mint bridging and
liquidity pool bridging, require depositing USDC liquidity into third-party
smart contracts. This approach reduces capital efficiency, acts as a target for
malicious attacks, and introduces additional trust assumptions.
Design Approach
Design Approach
As a low-level primitive, CCTP can be embedded within any app, wallet, or bridge
to enhance and simplify the user experience for crosschain use cases. With USDC
circulating across a large number of blockchain networks, CCTP connects and
unifies liquidity across the disparate ecosystems where it’s supported.CCTP is built on generalized message passing and designed for composability and
flexible use case enablement. Developers can extend its functionality beyond
just moving USDC between blockchains. For example, you can create a flow where
USDC is sent across chains and automatically deposited into a DeFi lending pool
after the transfer, allowing it to generate yield in an automated manner. This
experience can be designed to feel like a seamless, single transaction for the
end user.
How CCTP V2 works
CCTP V2 enables seamless and secure transfers of USDC across blockchains through two transfer methods: Fast Transfer and Standard Transfer. Both involve burning USDC on the source chain and minting it on the destination chain, but the steps and speed differ:- Fast Transfer
- Standard Transfer
Fast Transfer is an advanced feature of CCTP V2 designed for speed-sensitive
use cases. It leverages Circle’s Attestation Service and
to enable faster-than-finality
(soft finality) transfers. The process involves the following steps:
- Initiation. A user accesses an app powered by CCTP V2 and initiates a Fast Transfer of USDC, specifying the recipient’s wallet address on the destination chain.
- Burn Event. The app facilitates a burn of the specified USDC amount on the source blockchain.
- Instant Attestation. Circle’s Attestation Service attests to the burn event after soft finality (which varies per chain) and issues a signed attestation.
- Fast Transfer Allowance Backing. Until hard finality is reached, the burned USDC amount is backed by Circle’s Fast Transfer Allowance. The Fast Transfer Allowance is temporarily debited by the burn amount.
- Mint event. The app explicitly fetches the signed attestation from Circle’s Attestation Service and uses it to mint USDC on the destination chain. A fee is collected onchain during this process.
- Fast Transfer Allowance Replenishment. Once the burn reaches finality on the source chain, the corresponding amount is credited back to Circle’s Fast Transfer Allowance.
- Completion. The recipient wallet address receives the newly minted USDC on the destination blockchain, completing the transfer.
CCTP V2 White PaperRead the
CCTP V2 White Paper
to learn about the motivation behind CCTP V2 and how the Fast Transfer
Allowance balances speed, risk, and capital efficiency in crosschain USDC
transfers.
Use Cases
CCTP enables developers to build novel crosschain apps that integrate functionalities like trading, lending, payments, NFTs, and gaming, while simplifying the user experience. Below are some practical examples of how you can leverage CCTP in your applications—expand any to learn more.Fast and secure crosschain rebalancing
Fast and secure crosschain rebalancing
Market makers, fillers/solvers, exchanges, and bridges can use CCTP to manage
liquidity more efficiently. By securely rebalancing USDC holdings across
blockchains, you can reduce operational costs, meet demand, and take advantage
of market opportunities with minimal latency.
Composable crosschain swaps
Composable crosschain swaps
With CCTP, users can quickly swap between digital assets on different
blockchains by routing through USDC. Users can also swap for USDC and
automatically trigger subsequent actions on the destination chain, seamlessly
enabling complex crosschain actions such as swaps and deposits.
Programmable crosschain purchases
Programmable crosschain purchases
Automate crosschain purchases with CCTP. For example, a user can use USDC on one
chain to purchase an NFT on a decentralized exchange on another chain and list
it for sale on an NFT marketplace. When the transaction is initiated, CCTP
routes USDC across chains to buy the NFT and opens the listing on the
marketplace—all in one streamlined flow.
Simplify crosschain complexities
Simplify crosschain complexities
Simplify the crosschain experience by using USDC as collateral on one chain to
open a borrowing position on a lending protocol on another chain. With CCTP,
USDC can move quickly between blockchains, allowing users to onboard to new
applications without switching wallets or managing multichain complexities.
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