ARChemist: Autonomous Robotic Chemistry System Architecture

Fakhruldeen, Hatem; Pizzuto, Gabriella; Głowacki, Maciej; Cooper, Andrew I.

doi:10.48550/arxiv.2204.13571

Cited by 2 publications

(3 citation statements)

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“…Our evaluation results demonstrate that CLAIRify outperforms the current state-of-the-art model for XDL generation presented in (Mehr et al, 2020). Additionally, our framework represents an advancement from the approach in (Fakhruldeen et al, 2022), which relied on a finite state machine with fixed objects in a static workspace. Our framework perceives the environment and plans long-horizon trajectories to perform multistep chemistry experiments.…”

Section: Contributionsmentioning

confidence: 86%

“…The utility of mobile general-purpose robots for discovering improved photocatalysts for hydrogen production was demonstrated in (Burger et al, 2020). ARChemist (Fakhruldeen et al, 2022), a lab automation system, was developed to conduct experiments, including solubility screening and crystallization, without human intervention. Another work (Knobbe et al, 2022) endowed a collaborative robot with a force-sensitive pipetting skill by extending the robot with a pipetting finger system.…”

Section: Lab Automationmentioning

confidence: 99%

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Large language models for chemistry robotics

Yoshikawa,

Skreta,

Darvish

et al. 2023

Auton Robot

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This paper proposes an approach to automate chemistry experiments using robots by translating natural language instructions into robot-executable plans, using large language models together with task and motion planning. Adding natural language interfaces to autonomous chemistry experiment systems lowers the barrier to using complicated robotics systems and increases utility for non-expert users, but translating natural language experiment descriptions from users into low-level robotics languages is nontrivial. Furthermore, while recent advances have used large language models to generate task plans, reliably executing those plans in the real world by an embodied agent remains challenging. To enable autonomous chemistry experiments and alleviate the workload of chemists, robots must interpret natural language commands, perceive the workspace, autonomously plan multi-step actions and motions, consider safety precautions, and interact with various laboratory equipment. Our approach, CLAIRify, combines automatic iterative prompting with program verification to ensure syntactically valid programs in a data-scarce domain-specific language that incorporates environmental constraints. The generated plan is executed through solving a constrained task and motion planning problem using PDDLStream solvers to prevent spillages of liquids as well as collisions in chemistry labs. We demonstrate the effectiveness of our approach in planning chemistry experiments, with plans successfully executed on a real robot using a repertoire of robot skills and lab tools. Specifically, we showcase the utility of our framework in pouring skills for various materials and two fundamental chemical experiments for materials synthesis: solubility and recrystallization. Further details about CLAIRify can be found at https://ac-rad.github.io/clairify/.

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Section: Contributionsmentioning

confidence: 86%

Section: Lab Automationmentioning

confidence: 99%

Large language models for chemistry robotics

Yoshikawa,

Skreta,

Darvish

et al. 2023

Auton Robot

View full text Add to dashboard Cite

show abstract

“…1a)). [9][10][11][12][13][14][15] To keep the pace of automated synthesis, fast and reliable characterization of reaction products through spectroscopic methods is required, an oen manual, time intense and possibly error prone task. One of the most common methods to elucidate the structure of reaction products are nuclear magnetic resonance (NMR) experiments.…”

Section: Introductionmentioning

confidence: 99%