@article{He2026, 
author = {Bing He and Zhou Jiang and Kaixuan Wang and Qingbao Wang and Zhicong Lai and Yueyu Zhang and Maxim Avdeev and Siqi Shi},
title = {Multirole collaborative and co-constructive materials design ecosystem enabled by using control and data flows decoupled workflows},
year = {2026},
journal = {Journal of Materiomics},
volume = {12},
number = {2},
keywords = {Materials discovery and design, Multirole collaborative and co-constructive materials design ecosystem, Customized materials design infrastructure, Workflow system},
url = {https://www.sciopen.com/article/10.1016/j.jmat.2026.101177},
doi = {10.1016/j.jmat.2026.101177},
abstract = {Data-driven approaches are attracting wide attention in the field of materials science due to their capacity to unravel complex structure-activity relationships deriving from nonlinear interplay of materials properties across multiple scales. However, unlocking their potential in materials discovery and design requires addressing two main challenges: multi-disciplinary knowledge barriers across the entire materials data lifecycle (acquisition, processing, and analysis), and the absence of an infrastructure that can accommodate the continuous proliferation of data volume, algorithms, and models. Here, we propose a multirole collaborative and co-constructive materials design ecosystem that restructures both the productive forces and the relations of production in materials design. By establishing a structured division of labor and a customized materials design infrastructure with a workflow system that decouples control and data flows, our framework reduces inter-module dependencies and enables the flexible, scalable integration of heterogeneous resources. A case study on electrochemical storage materials design demonstrates that this approach can improve streamlined collaborative efficiency by at least 50%, highlighting its potential to accelerate materials design. This work establishes a new paradigm for building intelligent materials design platforms, characterized by dynamic composability instead of static integration, thereby fostering an open and sustainable ecosystem for future materials discovery.}
}