MARS: Co-evolving Dual-System Deep Research via Multi-Agent Reinforcement Learning
Abstract
Large Reasoning Models (LRMs) face two fundamental limitations: excessive token consumption when overanalyzing simple information processing tasks, and inability to access up-to-date knowledge beyond their training data. We introduce MARS (Multi-Agent System for Deep ReSearch), a novel co-evolution framework that jointly optimizes dual cognitive systems through multi-agent reinforcement learning. Unlike prior approaches that employ fixed or independently-trained summarizers, MARS enables System 1 (fast, intuitive processing) and System 2 (deliberate reasoning) to co-adapt through shared trajectory rewards, developing complementary strategies where System 1 learns to distill information specifically useful for System 2's reasoning. We extend Group Relative Policy Optimization (GRPO) for multi-agent settings with three key innovations: (1) decoupled gradient computation ensuring proper credit assignment despite shared rewards, (2) bin-packing optimization for efficient parallel information processing, and (3) advantage-weighted balanced sampling preventing training imbalance. Extensive experiments demonstrate that MARS (8B), trained under a challenging Zero RL setting without any supervised fine-tuning, achieves 8.17% on HLE -- outperforming WebThinker (32B with SFT, 6.87%) and narrowing the gap with proprietary models like Claude 3.7 Sonnet (7.89%) -- while achieving an average gain of 8.9% across 7 knowledge-intensive tasks.
Cite
@article{arxiv.2510.04935,
title = {MARS: Co-evolving Dual-System Deep Research via Multi-Agent Reinforcement Learning},
author = {Guoxin Chen and Zile Qiao and Wenqing Wang and Donglei Yu and Xuanzhong Chen and Hao Sun and Minpeng Liao and Kai Fan and Yong Jiang and Penguin Xie and Wayne Xin Zhao and Ruihua Song and Fei Huang},
journal= {arXiv preprint arXiv:2510.04935},
year = {2026}
}
Comments
Ongoing Work