Research

Concurrent Proposer MEV Model Secures High-Throughput Decentralized Block Production

Analyzing the Multiple Concurrent Proposer (MCP) architecture reveals new MEV channels; deterministic DAG scheduling neutralizes them, securing scalable concurrency.
December 7, 20254 min

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Briefing

The foundational problem of centralized Maximal Extractable Value (MEV) in sequential blockchains is addressed by the Multiple Concurrent Proposer (MCP) architecture, which allows multiple blocks to be proposed simultaneously. This breakthrough, however, introduces new, complex MEV channels like same-tick duplicate steals and proposer-to-proposer auctions, which the research formalizes using a hazard normalized model of delay and inclusion. The single most important implication is the proposal of architectural primitives, specifically deterministic priority DAG scheduling and duplicate aware payouts, which demonstrably neutralize these new concurrent MEV vectors, securing a path toward truly scalable and decentralized consensus mechanisms.

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Context

Traditional Proof-of-Stake and Proof-of-Work blockchains rely on a single, serial proposer per block slot, granting that entity a temporary, absolute monopoly over transaction inclusion and ordering. This single-builder assumption is the root cause of centralized MEV extraction, where validators exploit their privileged position to extract rents. Prior attempts to mitigate this relied on encryption-based mempools or complex auction mechanisms, which often failed to provide the necessary properties of selective-censorship resistance and hiding against a powerful single proposer. The challenge is to break this serial monopoly without introducing new, equally exploitable economic attack vectors.

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Analysis

The core mechanism analyzed is the Multiple Concurrent Proposer (MCP) model, which decouples block proposal from final ordering. In this model, multiple proposers publish blocks to a Data Availability (DA) layer in the same system “tick” before a final consensus determines the execution order. The paper’s conceptual breakthrough is the analytical framework that characterizes the economic equilibria of the new MEV games this concurrency creates. It proposes that by implementing deterministic priority DAG scheduling → which resolves ordering conflicts based on a fixed, non-manipulable rule → and duplicate aware payouts → which penalize or neutralize rewards for duplicate transactions → the new MEV channels are structurally eliminated without sacrificing the high throughput enabled by concurrency.

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Parameters

  • Tick Duration – System Latency → 300ms. The approximate time interval between consensus proposals in the example MCP protocol, demonstrating the high-frequency environment being analyzed.
  • New MEV Channels – Concurrent Vectors → Same Tick Duplicate Steals. A new form of MEV unique to MCP where a proposer can frontrun or steal a transaction included in a concurrent block.
  • Mitigation Primitive – Scheduling Mechanism → Deterministic Priority DAG Scheduling. The proposed architectural solution for resolving concurrent block ordering conflicts in a non-exploitable manner.

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Outlook

This research establishes the foundational economic and architectural requirements for securing the next generation of high-throughput, concurrent consensus protocols. The principles of deterministic DAG scheduling and duplicate-aware incentives will become standard building blocks for all future systems that aim to scale by breaking the serial bottleneck. This work opens new research avenues in formalizing the trade-offs between concurrency, finality latency, and the complete elimination of all MEV types, providing a roadmap for achieving scalable, fair, and decentralized transaction processing within the next three to five years.

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Verdict

The formal characterization of concurrent MEV and its mitigation via deterministic scheduling provides the essential security primitives for the next era of high-performance, decentralized blockchain architectures.

Maximal extractable value, Concurrent proposer model, Transaction ordering fairness, Deterministic DAG scheduling, Proof of availability, Consensus protocol security, Censorship resistance mechanism, Protocol configuration, Economic game theory, Hazard normalized model, Decentralized block production, Same tick MEV, Duplicate aware payouts, High throughput consensus, Scalable decentralized systems, Transaction inclusion delay, Proposer-to-proposer auctions Signal Acquired from → arxiv.org

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maximal extractable value

Definition ∞ Maximal Extractable Value (MEV) refers to the profit that can be obtained by block producers by strategically including, excluding, or reordering transactions within a block they are creating.

censorship resistance

Definition ∞ Censorship resistance is a core characteristic of decentralized systems that prevents any single entity from blocking or altering transactions or data.

high throughput

Definition ∞ High throughput denotes the capacity of a blockchain network or system to process a large volume of transactions within a given period.

protocol

Definition ∞ A protocol is a set of rules governing data exchange or communication between systems.

transaction

Definition ∞ A transaction is a record of the movement of digital assets or the execution of a smart contract on a blockchain.

scheduling

Definition ∞ Scheduling refers to the process of planning and arranging events or activities at specific times.

decentralized

Definition ∞ Decentralized describes a system or organization that is not controlled by a single central authority.

mev

Definition ∞ MEV, or Miner Extractable Value, represents the profit that block producers can obtain by strategically including, excluding, or reordering transactions within a block.

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