Search result of STM

This article delves into the Move programming language and its applications in the blockchain space, particularly focusing on Sui and Aptos, two Layer 1 blockchains built on Move. The piece analyzes Move's advantages in security, composability, and performance, offering an in-depth look at the architecture, consensus mechanisms, and technical innovations of Sui and Aptos. It also explores the development potential and current challenges of the Move ecosystem, along with Sui's applications in gaming and Aptos' collaboration with Microsoft

Aptos is a Layer 1 blockchain designed with core principles of scalability, security, reliability, and upgradeability.

Competition in the Alt L1 space is heating up, with Near introducing a DA solution and Sui's TVL steadily rising. While Ethereum takes its time with mainnet upgrades, L2 introduces two major competitive points: parallel EVM and decentralized sequencers.

This article explains in detail the Layer 1 public chain project Aptos, from its history, consensus mechanism, token economics, and VM characteristics, to its ecosystem projects.

The article compares the Move ecosystem's Aptos and Sui across multiple dimensions, from technical infrastructure to ecological applications.

This article details the operation of EVM as the core of Ethereum, and explores the innovations made by high-performance Layer1 blockchains in terms of parallel execution and virtual machine selection. In the future, more Layer 1s will implement EVM parallel upgrades or EVM compatible solutions to promote the diverse development of the blockchain ecosystem.

Founded by former Meta's Diem employees and built using Move programming language, the Aptos blockchain promises to solve issues faced by decentralized systems.

Shoal Research, an encryption research institution, analyzed the current related projects in the parallel field of blockchain, including the progress of Solana (SVM), parallel EVM (Sei, Monad) and MoveVM (Aptos, Sui, Movement), and analyzed the challenges faced in this field. and opportunities.

The article explores the application of parallel execution technology in the blockchain domain, particularly how it enhances transaction efficiency, reduces costs, and improves user experience. Solana, as a pioneer of parallel execution, demonstrates its advantages in processing speed and throughput. The article provides a detailed explanation of how blockchain transactions work, including the transaction lifecycle, the role of the mempool, and the operation of blockchains without a mempool. Parallel execution allows blockchains to process multiple non-conflicting transactions simultaneously, thereby increasing network throughput and scalability. The article also discusses different models of parallel execution, including deterministic and optimistic models, and analyzes the teams and projects driving parallel execution in the market, such as Solana, Parallel EVM, Sei Network, Monad, Move language, Aptos, Sui, and Movement Labs.

This article explores Parallel EVM technology, and its applications and potential in blockchain. It has attracted attention and investment from leading venture capital firms. Parallel EVM supports more complex and efficient blockchain applications through comprehensive performance optimization, achieving differentiation in the open-source ecosystem while balancing decentralization and high-performance needs. The article analyzes the technical challenges of Parallel EVM, such as data consistency, state access efficiency, and transaction conflict detection, and introduces unique solutions from projects like MegaETH and Artela.

This article comprehensively outlines the scalability paths of Web3 parallel computing, covering mainstream architectures such as Monad, MegaETH, Sui, and Solana. It reveals the key design concepts and development trends of the next generation of high-performance blockchains, from account-level and object-level to the Actor model.

Today we’re excited to share Reth’s path towards 1 gigagas per second in L2 in 2024, and our longer-term roadmap for going beyond that.

This article provides an in-depth analysis of the technical architecture, consensus mechanisms, user experience, and community ecosystems of Sui, Aptos, and Movement. It highlights their differences in performance, costs, stability, and hardware wallet compatibility.

This article explores the technical details and market prospects of parallel EVMs, analyzing the parallel execution mechanisms of major blockchain projects such as Sei, Monad, and Canto, and evaluating their potential impact and market position in the industry. Through parallel execution optimization, blockchain networks can significantly enhance processing speed and efficiency, supporting the widespread development of the Web3 domain.

Benjamin Funk, the researcher of the crypto investment institution Archetype, attributes the execution layer's bottleneck to inefficient state access and computation. He has evaluated the design choices made by integrated and modular execution environments in achieving higher performance and expanding the range of on-chain applications.