Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions

Umadini Ranasinghe; Abigail L. Stressinger; Guangpeng Xu; Yasmin Sarhan; James Berry; Tim Thomay

doi:10.1364/quantum.2025.qtu3a.28

Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions

Umadini Ranasinghe
, Abigail L. Stressinger
, Guangpeng Xu
, Yasmin Sarhan
, James Berry
, Tim Thomay

SUNY Buffalo

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

We developed a quantum fingerprint for plants using higher order photon correlation based on quantum light emitters. Overcoming classical limitations, this approach allows us to classify leaves as healthy or unhealthy enabling optimized plant growth.

Original language	English
Title of host publication	Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition
Publisher	Optical Society of America
ISBN (Electronic)	9781957171487
DOIs	https://doi.org/10.1364/quantum.2025.qtu3a.28
State	Published - 2025
Event	Optica Quantum 2.0 Conference and Exhibition, QUANTUM 2025 - San Francisco, United States Duration: Jun 1 2025 → Jun 5 2025

Publication series

Name	Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition

Conference

Conference	Optica Quantum 2.0 Conference and Exhibition, QUANTUM 2025
Country/Territory	United States
City	San Francisco
Period	06/1/25 → 06/5/25

Access to Document

10.1364/quantum.2025.qtu3a.28

Cite this

Ranasinghe, U., Stressinger, A. L., Xu, G., Sarhan, Y., Berry, J., & Thomay, T. (2025). Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions. In Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition Article QTu3A.28 (Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition). Optical Society of America. https://doi.org/10.1364/quantum.2025.qtu3a.28

@inproceedings{323378f2a45f4ee8b0ed2a482af3b666,

title = "Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions",

abstract = "We developed a quantum fingerprint for plants using higher order photon correlation based on quantum light emitters. Overcoming classical limitations, this approach allows us to classify leaves as healthy or unhealthy enabling optimized plant growth.",

author = "Umadini Ranasinghe and Stressinger, \{Abigail L.\} and Guangpeng Xu and Yasmin Sarhan and James Berry and Tim Thomay",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s).; Optica Quantum 2.0 Conference and Exhibition, QUANTUM 2025 ; Conference date: 01-06-2025 Through 05-06-2025",

year = "2025",

doi = "10.1364/quantum.2025.qtu3a.28",

language = "English",

series = "Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition",

publisher = "Optical Society of America",

booktitle = "Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition",

}

Ranasinghe, U, Stressinger, AL, Xu, G, Sarhan, Y, Berry, J & Thomay, T 2025, Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions. in Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition., QTu3A.28, Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition, Optical Society of America, Optica Quantum 2.0 Conference and Exhibition, QUANTUM 2025, San Francisco, United States, 06/1/25. https://doi.org/10.1364/quantum.2025.qtu3a.28

Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions. / Ranasinghe, Umadini; Stressinger, Abigail L.; Xu, Guangpeng et al.
Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition. Optical Society of America, 2025. QTu3A.28 (Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions

AU - Ranasinghe, Umadini

AU - Stressinger, Abigail L.

AU - Xu, Guangpeng

AU - Sarhan, Yasmin

AU - Berry, James

AU - Thomay, Tim

PY - 2025

Y1 - 2025

N2 - We developed a quantum fingerprint for plants using higher order photon correlation based on quantum light emitters. Overcoming classical limitations, this approach allows us to classify leaves as healthy or unhealthy enabling optimized plant growth.

AB - We developed a quantum fingerprint for plants using higher order photon correlation based on quantum light emitters. Overcoming classical limitations, this approach allows us to classify leaves as healthy or unhealthy enabling optimized plant growth.

UR - https://www.scopus.com/pages/publications/105013079484

U2 - 10.1364/quantum.2025.qtu3a.28

DO - 10.1364/quantum.2025.qtu3a.28

M3 - Conference contribution

AN - SCOPUS:105013079484

T3 - Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition

BT - Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition

PB - Optical Society of America

T2 - Optica Quantum 2.0 Conference and Exhibition, QUANTUM 2025

Y2 - 1 June 2025 through 5 June 2025

ER -

Ranasinghe U, Stressinger AL, Xu G, Sarhan Y, Berry J , Thomay T. Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions. In Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition. Optical Society of America. 2025. QTu3A.28. (Quantum 2.0 in Proceedings Optica Quantum 2.0 Conference and Exhibition). doi: 10.1364/quantum.2025.qtu3a.28

Utilizing Quantum Fingerprints in Plant Cells to Optimize Growth Conditions

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