Delocalized, asynchronous, closed-loop discovery of organic laser emitters

Felix Strieth-Kalthoff; Han Hao; Vandana Rathore; Joshua Derasp; Théophile Gaudin; Nicholas H Angello; Martin Seifrid; Ekaterina Trushina; Mason Guy; Junliang Liu; Xun Tang; Masashi Mamada; Wesley Wang; Tuul Tsagaantsooj; Cyrille Lavigne; Robert Pollice; Tony C Wu; Kazuhiro Hotta; Leticia Bodo; Shangyu Li; Mohammad Haddadnia; Agnieszka Wołos; Rafał Roszak; Cher Tian Ser; Carlota Bozal-Ginesta; Riley J Hickman; Jenya Vestfrid; Andrés Aguilar-Granda; Elena L Klimareva; Ralph C Sigerson; Wenduan Hou; Daniel Gahler; Slawomir Lach; Adrian Warzybok; Oleg Borodin; Simon Rohrbach; Benjamin Sanchez-Lengeling; Chihaya Adachi; Bartosz A Grzybowski; Leroy Cronin; Jason E Hein; Martin D Burke; Alán Aspuru-Guzik

doi:10.1126/science.adk9227

Delocalized, asynchronous, closed-loop discovery of organic laser emitters

Felix Strieth-Kalthoff, Han Hao, Vandana Rathore, Joshua Derasp, Théophile Gaudin, Nicholas H Angello, Martin Seifrid, Ekaterina Trushina, Mason Guy, Junliang Liu, Xun Tang, Masashi Mamada, Wesley Wang, Tuul Tsagaantsooj, Cyrille Lavigne, Robert Pollice, Tony C Wu, Kazuhiro Hotta, Leticia Bodo, Shangyu LiMohammad Haddadnia, Agnieszka Wołos, Rafał Roszak, Cher Tian Ser, Carlota Bozal-Ginesta, Riley J Hickman, Jenya Vestfrid, Andrés Aguilar-Granda, Elena L Klimareva, Ralph C Sigerson, Wenduan Hou, Daniel Gahler, Slawomir Lach, Adrian Warzybok, Oleg Borodin, Simon Rohrbach, Benjamin Sanchez-Lengeling, Chihaya Adachi^*, Bartosz A Grzybowski^*, Leroy Cronin^*, Jason E Hein^*, Martin D Burke^*, Alán Aspuru-Guzik^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

41 Citations (Scopus)

Abstract

Contemporary materials discovery requires intricate sequences of synthesis, formulation, and characterization that often span multiple locations with specialized expertise or instrumentation. To accelerate these workflows, we present a cloud-based strategy that enabled delocalized and asynchronous design-make-test-analyze cycles. We showcased this approach through the exploration of molecular gain materials for organic solid-state lasers as a frontier application in molecular optoelectronics. Distributed robotic synthesis and in-line property characterization, orchestrated by a cloud-based artificial intelligence experiment planner, resulted in the discovery of 21 new state-of-the-art materials. Gram-scale synthesis ultimately allowed for the verification of best-in-class stimulated emission in a thin-film device. Demonstrating the asynchronous integration of five laboratories across the globe, this workflow provides a blueprint for delocalizing-and democratizing-scientific discovery.

Original language	English
Article number	eadk9227
Number of pages	10
Journal	Science (New York, N.Y.)
Volume	384
Issue number	6697
DOIs	https://doi.org/10.1126/science.adk9227
Publication status	Published - 17-May-2024
Externally published	Yes

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Strieth-Kalthoff, F., Hao, H., Rathore, V., Derasp, J., Gaudin, T., Angello, N. H., Seifrid, M., Trushina, E., Guy, M., Liu, J., Tang, X., Mamada, M., Wang, W., Tsagaantsooj, T., Lavigne, C., Pollice, R., Wu, T. C., Hotta, K., Bodo, L., ... Aspuru-Guzik, A. (2024). Delocalized, asynchronous, closed-loop discovery of organic laser emitters. Science (New York, N.Y.), 384(6697), Article eadk9227. https://doi.org/10.1126/science.adk9227

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title = "Delocalized, asynchronous, closed-loop discovery of organic laser emitters",

abstract = "Contemporary materials discovery requires intricate sequences of synthesis, formulation, and characterization that often span multiple locations with specialized expertise or instrumentation. To accelerate these workflows, we present a cloud-based strategy that enabled delocalized and asynchronous design-make-test-analyze cycles. We showcased this approach through the exploration of molecular gain materials for organic solid-state lasers as a frontier application in molecular optoelectronics. Distributed robotic synthesis and in-line property characterization, orchestrated by a cloud-based artificial intelligence experiment planner, resulted in the discovery of 21 new state-of-the-art materials. Gram-scale synthesis ultimately allowed for the verification of best-in-class stimulated emission in a thin-film device. Demonstrating the asynchronous integration of five laboratories across the globe, this workflow provides a blueprint for delocalizing-and democratizing-scientific discovery.",

author = "Felix Strieth-Kalthoff and Han Hao and Vandana Rathore and Joshua Derasp and Th{\'e}ophile Gaudin and Angello, {Nicholas H} and Martin Seifrid and Ekaterina Trushina and Mason Guy and Junliang Liu and Xun Tang and Masashi Mamada and Wesley Wang and Tuul Tsagaantsooj and Cyrille Lavigne and Robert Pollice and Wu, {Tony C} and Kazuhiro Hotta and Leticia Bodo and Shangyu Li and Mohammad Haddadnia and Agnieszka Wo{\l}os and Rafa{\l} Roszak and Ser, {Cher Tian} and Carlota Bozal-Ginesta and Hickman, {Riley J} and Jenya Vestfrid and Andr{\'e}s Aguilar-Granda and Klimareva, {Elena L} and Sigerson, {Ralph C} and Wenduan Hou and Daniel Gahler and Slawomir Lach and Adrian Warzybok and Oleg Borodin and Simon Rohrbach and Benjamin Sanchez-Lengeling and Chihaya Adachi and Grzybowski, {Bartosz A} and Leroy Cronin and Hein, {Jason E} and Burke, {Martin D} and Al{\'a}n Aspuru-Guzik",

year = "2024",

month = may,

day = "17",

doi = "10.1126/science.adk9227",

language = "English",

volume = "384",

journal = "Science (New York, N.Y.)",

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Strieth-Kalthoff, F, Hao, H, Rathore, V, Derasp, J, Gaudin, T, Angello, NH, Seifrid, M, Trushina, E, Guy, M, Liu, J, Tang, X, Mamada, M, Wang, W, Tsagaantsooj, T, Lavigne, C, Pollice, R, Wu, TC, Hotta, K, Bodo, L, Li, S, Haddadnia, M, Wołos, A, Roszak, R, Ser, CT, Bozal-Ginesta, C, Hickman, RJ, Vestfrid, J, Aguilar-Granda, A, Klimareva, EL, Sigerson, RC, Hou, W, Gahler, D, Lach, S, Warzybok, A, Borodin, O, Rohrbach, S, Sanchez-Lengeling, B, Adachi, C, Grzybowski, BA, Cronin, L, Hein, JE, Burke, MD & Aspuru-Guzik, A 2024, 'Delocalized, asynchronous, closed-loop discovery of organic laser emitters', Science (New York, N.Y.), vol. 384, no. 6697, eadk9227. https://doi.org/10.1126/science.adk9227

TY - JOUR

T1 - Delocalized, asynchronous, closed-loop discovery of organic laser emitters

AU - Strieth-Kalthoff, Felix

AU - Hao, Han

AU - Rathore, Vandana

AU - Derasp, Joshua

AU - Gaudin, Théophile

AU - Angello, Nicholas H

AU - Seifrid, Martin

AU - Trushina, Ekaterina

AU - Guy, Mason

AU - Liu, Junliang

AU - Tang, Xun

AU - Mamada, Masashi

AU - Wang, Wesley

AU - Tsagaantsooj, Tuul

AU - Lavigne, Cyrille

AU - Pollice, Robert

AU - Wu, Tony C

AU - Hotta, Kazuhiro

AU - Bodo, Leticia

AU - Li, Shangyu

AU - Haddadnia, Mohammad

AU - Wołos, Agnieszka

AU - Roszak, Rafał

AU - Ser, Cher Tian

AU - Bozal-Ginesta, Carlota

AU - Hickman, Riley J

AU - Vestfrid, Jenya

AU - Aguilar-Granda, Andrés

AU - Klimareva, Elena L

AU - Sigerson, Ralph C

AU - Hou, Wenduan

AU - Gahler, Daniel

AU - Lach, Slawomir

AU - Warzybok, Adrian

AU - Borodin, Oleg

AU - Rohrbach, Simon

AU - Sanchez-Lengeling, Benjamin

AU - Adachi, Chihaya

AU - Grzybowski, Bartosz A

AU - Cronin, Leroy

AU - Hein, Jason E

AU - Burke, Martin D

AU - Aspuru-Guzik, Alán

PY - 2024/5/17

Y1 - 2024/5/17

N2 - Contemporary materials discovery requires intricate sequences of synthesis, formulation, and characterization that often span multiple locations with specialized expertise or instrumentation. To accelerate these workflows, we present a cloud-based strategy that enabled delocalized and asynchronous design-make-test-analyze cycles. We showcased this approach through the exploration of molecular gain materials for organic solid-state lasers as a frontier application in molecular optoelectronics. Distributed robotic synthesis and in-line property characterization, orchestrated by a cloud-based artificial intelligence experiment planner, resulted in the discovery of 21 new state-of-the-art materials. Gram-scale synthesis ultimately allowed for the verification of best-in-class stimulated emission in a thin-film device. Demonstrating the asynchronous integration of five laboratories across the globe, this workflow provides a blueprint for delocalizing-and democratizing-scientific discovery.

AB - Contemporary materials discovery requires intricate sequences of synthesis, formulation, and characterization that often span multiple locations with specialized expertise or instrumentation. To accelerate these workflows, we present a cloud-based strategy that enabled delocalized and asynchronous design-make-test-analyze cycles. We showcased this approach through the exploration of molecular gain materials for organic solid-state lasers as a frontier application in molecular optoelectronics. Distributed robotic synthesis and in-line property characterization, orchestrated by a cloud-based artificial intelligence experiment planner, resulted in the discovery of 21 new state-of-the-art materials. Gram-scale synthesis ultimately allowed for the verification of best-in-class stimulated emission in a thin-film device. Demonstrating the asynchronous integration of five laboratories across the globe, this workflow provides a blueprint for delocalizing-and democratizing-scientific discovery.

U2 - 10.1126/science.adk9227

DO - 10.1126/science.adk9227

M3 - Article

C2 - 38753786

SN - 0036-8075

VL - 384

JO - Science (New York, N.Y.)

JF - Science (New York, N.Y.)

IS - 6697

M1 - eadk9227

ER -

Delocalized, asynchronous, closed-loop discovery of organic laser emitters

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