This readme.txt file was generated on 20250523 by Kristine Q. Loh Recommended citation for the data: Loh, Kristine Q; Eylands, Nathan J; Ferry, Vivian E; Kortshagen, Uwe R. (2025). Supporting Data for Spectral Engineering with Quantum Dot Films for Enhanced Lettuce Growth. Retrieved from the Data Repository for the University of Minnesota (DRUM), https://doi.org/10.13020/kafz-yc82 ------------------- GENERAL INFORMATION ------------------- 1. Supporting Data for Spectral Engineering with Quantum Dot Films for Enhanced Lettuce Growth 2. Author Information Principal Investigator Contact Information Name: Uwe R. Kortshagen Institution: Univeristy of Minnesota Address: 111 Church St SE, Minneapolis, MN 55455 Email: korts001@umn.edu ORCID: https://orcid.org/0000-0001-5944-3656 Associate or Co-investigator Contact Information Name: Vivian E. Ferry Institution: University of Minnesota Address: 421 Washington Ave SE, Minneapolis, MN 55455 Email: veferry@umn.edu ORCID: https://orcid.org/0000-0002-9676-6056 Associate or Co-investigator Contact Information Name: Nathan J. Eylands Institution: University of Minnesota Address: 1970 Folwell Ave, St Paul, MN 55108 Email: neylands@umn.edu ORCID: https://orcid.org/0000-0002-4725-0088 Associate or Co-investigator Contact Information Name: Kristine Q. Loh Institution: University of Minnesota Address: 421 Washington Ave SE, Minneapolis, MN 55455 Email: loh00014@umn.edu ORCID: https://orcid.org/0000-0001-5205-157X 3. Date published or finalized for release: 2025-05-29 4. Date of data collection (single date, range, approximate date) 20241001 - 20250102 5. Geographic location of data collection (where was data collected?): Minneapolis, MN, USA 6. Information about funding sources that supported the collection of the data: K.Q.L. was partially supported by the National Science Foundation Graduate Research Fellowship under grant no. 2237827 and received support from the University of Minnesota under the Ronald L. and Janet A. Christenson Chair in Renewable Energy. 7. Overview of the data (abstract): To improve crop yields without the added cost of supplementary lighting, passive spectral manipulation shifts sunlight into critical wavebands for plant growth. Quantum dot (QD) films shift higher energy photons to lower energies, serving as tunable sunlight filters, but are understudied in this application space. Herein, we identify QD film properties to pro-mote lettuce growth. By simulating films with nine different nontoxic QDs, we calculate a concentration-dependent lettuce yield improvement of up to 45%. QDs that strongly absorb blue/green light and downshift this light to red/far-red wavebands result in the highest lettuce yield enhancements. Despite this strong absorption, we find that QD films can be utilized broadly in the United States. Contrary to common intuition, increasing the photoluminescence quantum yield or film outcoupling efficiency does not further increase lettuce yield, indicating that filtered absorption is the most important factor in design. This study points to the need for more directed investigation into QD films for increasing plant growth. -------------------------- SHARING/ACCESS INFORMATION -------------------------- 1. Licenses/restrictions placed on the data: CC0 1.0 Universal http://creativecommons.org/publicdomain/zero/1.0/ 2. Links to publications that cite or use the data: Loh, K. Q., Eylands, N. J., Ferry, V. E., & Kortshagen, U. R. (2025). Spectral Engineering with Quantum Dot Films for Enhanced Crop Growth. ACS Applied Optical Materials. https://doi.org/10.1021/acsaom.5c00338 3. Terms of Use: Data Repository for the U of Minnesota (DRUM) By using these files, users agree to the Terms of Use. https://conservancy.umn.edu/pages/policies/#drum-terms-of-use --------------------- DATA & FILE OVERVIEW --------------------- 1. File List A. Filename: Figure1.csv Short description: This file contains the data that was used to generate Figure 1. Figure 1 displayed the absorption and photoluminescence spectra of all nine nontoxic nanomaterials studied in the main text. B. Filename: Figure2.csv Short description: This file contains the data that was used to generate Figure 2. Figure 2(a) showed a schematic of control over the extended daily light integral (eDLI) through a spectral shifting QD film to demonstrate the dependent and independent variables. Next to the schematic was the calculated change in dry weight of lettuce compared to lettuce grown under the solar spectrum (12.5 g) is a function of quantum dot (QD) selection and concentration. Figure 2(b) showed a schematic of the required outdoor eDLI to meet a constant eDLI of 19.2 mol · m^­2 · d^­1 for plant growth. With increasing concentration, the required outdoor eDLI increases up to 45 mol · m^­2 · d^­1, depending on QD selection. QD films that resulted in the greatest yield enhancements (r-CDots, Si, and InP/ZnSe) had additional labels. C. Filename: Figure 3.csv Short description: This file contains the data that was used to generated Figure 3. Figure 3 showed extended daily light integral maps across the United States throughout the year, assuming the greenhouse framing blocked 20% of incident light. D. Filename: Figure 4a_c.csv Short description: This file contains the data that was used to generated Figure 4(a) - (c). Figure 4 showed the change in dry weight in a 10 wt% film as a function of the photoluminescence quantum yield (Figure 4(a) – (c)) and as a function of the film outcoupling efficiency (Figure 4(d) – (f)). Figure 4(a) showed the changes in dry weight for carbon dot films, Figure 4(b) showed the changes in dry weight for quantum dot films with visible photoluminescence, and Figure 4(c) showed the changes in dry weight for quantum dot films with near infrared photoluminescence. D. Filename: Figure 4d_f.csv Short description: This file contains the data that was used to generated Figure 4(d) - (f). Figure 4 showed the change in dry weight in a 10 wt% film as a function of the photoluminescence quantum yield (Figure 4(a) – (c)) and as a function of the film outcoupling efficiency (Figure 4(d) – (f)). Figure 4(d) showed the changes in dry weight for carbon dot films, Figure 4(e) showed the changes in dry weight for quantum dot films with visible photoluminescence, and Figure 4(f) showed the changes in dry weight for quantum dot films with near infrared photoluminescence. E. Filename: FigureS1.csv Short description: This file contains the data that was used to generate Figure S1. Figure S1 displayed the absorption coefficients of all nine nontoxic nanomaterials studied in the main text. F. Filename: FigureS2.csv Short description: This file contains the data that was used to generate Figure S2. Figure S2 re-presented the absorptance and relative quantum yield reported by McCree (McCree, Agricultural Meteorology, 9, pp. 191-216 (1971), DOI: 10.1016/0002-1571(71)90022-7). G. Filename: FigureS3.csv Short description: This file contains the data that was used to generate Figure S3. Figure S3 demonstrated model validation based on experimentally reported growth trials by Kang et al. (Kang et al., HortScience, 59.7, pp. 988-996 (2024), DOI: 10.21273/HORTSCI17921-24). H. Filename: FigureS4.csv Short description: This file contains the data that was used to generate Figure S4. Figure S4 showed the dry weights of lettuce grown under all nine nontoxic QD films as reported in the main text. I. Filename: FigureS5.csv Short description: This file contains the data that was used to generate Figure S5. Figure S5 displayed the absorption and photoluminescence spectra of all eight cadmium- and lead-containing nanomaterials studied in the Supporting Information. J. Filename: FigureS6.csv Short description: This file contains the data that was used to generate Figure S6. Figure S2(a) showed the calculated change in dry weight of lettuce compared to lettuce grown under the solar spectrum (12.5 g) is a function of quantum dot (QD) selection and concentration. Figure 2(b) showed the required outdoor extended daily light integral to meet a constant eDLI of 19.2 mol · m^­2 · d^­1 for plant growth. With increasing concentration, the required outdoor eDLI increases up to 55 mol · m^­2 · d^­1, depending on QD selection. QD films that resulted in the greatest yield enhancements (CdSe/CdS and CdSe/Cd0.6Zn0.4S) had additional labels. K. Filename: FigureS7.csv Short description: This file contains the data that was used to generate Figure S7. Figure S7(a) showed the change in dry weight for lettuce under nontoxic quantum dot films if the extended daily light integral was kept at 5 mol · m^­2 · d^­1. Figure S7(b) showed the change in dry weight for lettuce under nontoxic quantum dot films if the extended daily light integral was kept at 10 mol · m^­2 · d^­1. L. Filename: FigureS8.csv Short description: This file contains the data that was used to generate Figure S8. Figure S8 showed the quantum use efficiency (cϵ) as a function of blue, green, red, and far-red color fractions assuming (a) FBI is set to 0, (b) FGI is set to 0, and (c) FFRI is set to 0. The source data in the model by Abedi et al. always included some red light, so the red light fraction cannot be set to 0. 2. Relationship between files: All files were used to generate the figures in both the main text and Supporting Information of the manuscript. -------------------------- METHODOLOGICAL INFORMATION -------------------------- 1. Description of methods used for collection/generation of data: The spectra in Figure 1 were retrieved from the literature using WebPlotDigitizer. The subsequent calculations were based on Snell's Law and the Beer-Lambert Law. We also used a lettuce yield model by Abedi et al. (DOI:10.3389/fpls.2023.1106576) to estimate crop yields as a function of transmitted spectrum and light intensity. Maps of the United States were generated using data from Logan and Faust in ArcGIS (https://webgis.coe.clemson.edu/storymaps/light-integral-map/). All calculations were conducted in MATLAB R2024a. 2. Methods for processing the data: MATLAB was used to convert the daily light integral (light from 400 - 700 nm) to the extended daily light integral (400 - 750 nm) in generating the U.S. light maps. 3. Instrument- or software-specific information needed to interpret the data: N/A 4. Standards and calibration information, if appropriate: N/A 5. Environmental/experimental conditions: N/A 6. Describe any quality-assurance procedures performed on the data: N/A 7. People involved with sample collection, processing, analysis and/or submission: Kristine Q. Loh, Nathan J. Eylands, Uwe R. Kortshagen, Vivian E. Ferry ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: Figure1.csv ----------------------------------------- 1. Number of variables: 19 2. Number of cases/rows: 3701 3. Variable List A. Name: Wavelength (nm) Description: Wavelength of light in nanometers B. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of red-emitting carbon dots (r-CDots) quantum dots in in arbitrary units. C. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of red-emitting carbon dots (r-CDots) quantum dots normalized to 1 in arbitrary units. D. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of green-emitting carbon dots (g-CDots) quantum dots in in arbitrary units. E. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of green-emitting carbon dots (g-CDots) quantum dots normalized to 1 in arbitrary units. F. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of blue-emitting carbon dots (b-CDots) quantum dots in in arbitrary units. G. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of blue-emitting carbon dots (b-CDots) quantum dots normalized to 1 in arbitrary units. H. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of copper indium sulfied/zinc sulfide (CIS/ZnS) quantum dots in in arbitrary units. I. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of copper indium sulfide/zinc sulfied (CIS/ZnS) quantum dots normalized to 1 in arbitrary units. J. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dots in in arbitrary units. K. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dots normalized to 1 in arbitrary units. L. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of copper iodide (Cu4I6(pr-ted)2) quantum dots in in arbitrary units. M. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of copper iodide (Cu4I6(pr-ted)2) quantum dots normalized to 1 in arbitrary units. N. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of silicon (Si) quantum dots in in arbitrary units. O. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of Silicon (Si) quantum dots normalized to 1 in arbitrary units. P. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dots in in arbitrary units. Q. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dots normalized to 1 in arbitrary units. R. Name: Normalized Absorbance (a.u.) Description: Normalized absorbance of indium phosphide/zinc selenide (InP/ZnSe) quantum dots in in arbitrary units S. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of indium phosphide/zinc selenide (InP/ZnSe) quantum dots normalized to 1 in arbitrary units. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: Figure2.csv ----------------------------------------- 1. Number of variables: 19 2. Number of cases/rows: 100 3. Variable List A. Name: Concentration (wt%) Description: Concentration of the quantum dots in the spectral shifting film in units of weight percent. B. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under red-emitting carbon dot (r-CDot) quantum dot films in units of percent. C. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement red-emitting carbon dot (r-CDot) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. D. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under green-emitting carbon dot (g-CDot) quantum dot films in units of percent. E. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement green-emitting carbon dot (g-CDot) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. F. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under blue-emitting carbon dot (b-CDot) quantum dot films in units of percent. G. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement blue-emitting carbon dot (b-CDot) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. H. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films in units of percent. I. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. J. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films in units of percent. K. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. L. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under copper iodide (Cu4I6(pr-ted)2) quantum dot films in units of percent. M. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement copper iodide (Cu4I6(pr-ted)2) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. N. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under silicon (Si) quantum dot films in units of percent. O. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement silicon (Si) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. P. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films in units of percent. Q. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. R. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films in units of percent. S. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement indium phosphide/zinc selenide (InP/ZnSe) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: Figure3.csv ----------------------------------------- 1. Number of variables: 15 2. Number of cases/rows: 88312 3. Variable List A. Name: Latitude (degrees) Description: Latitude of the simulated greenhouse. B. Name: Longitude (degrees) Description: Longitude of the simulated greenhouse. C. Name: Annual Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Annual average extended daily light integral in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. D. Name: January Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in January in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. E. Name: February Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in February in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. F. Name: March Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in March in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. G. Name: April Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in April in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. H. Name: May Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in May in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. I. Name: June Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in June in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. J. Name: July Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in July in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. K. Name: August Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in August in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. L. Name: September Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in September in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. M. Name: October Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in October in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. N. Name: November Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in November in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. O. Name: December Extended Daily Light Integral (eDLI) (mol/m^2/day) Description: Extended daily light integral in December in units of mol/m^2/day for a greenhouse in which framing blocks 20% of light. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: Figure4a_c.csv ----------------------------------------- 1. Number of variables: 19 2. Number of cases/rows: 11 3. Variable List A. Name: Photoluminescence Quantum Yield (PLQY) (%) Description: The photoluminescence quantum yield of the quantum dot in units of percentage. B. Name: Dry Weight (g) Description: Dry weight of lettuce produced under red-emitting carbon dot (r-CDot) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. C. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under red-emitting carbon dot (r-CDot) quantum dot films in units of percent. D. Name: Dry Weight (g) Description: Dry weight of lettuce produced under green-emitting carbon dot (g-CDot) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. E. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under green-emitting carbon dot (g-CDot) quantum dot films in units of percent. F. Name: Dry Weight (g) Description: Dry weight of lettuce produced under blue-emitting carbon dot (b-CDot) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. G. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under blue-emitting carbon dot (b-CDot) quantum dot films in units of percent. H. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. I. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films in units of percent. J. Name: Dry Weight (g) Description: Dry weight of lettuce produced under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. K. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films in units of percent. L. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper iodide (Cu4I6(pr-ted)2) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. M. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under copper iodide (Cu4I6(pr-ted)2) quantum dot films in units of percent. N. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silicon (Si) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. O. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under silicon (Si) quantum dot films in units of percent. P. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. Q. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films in units of percent. R. Name: Dry Weight (g) Description: Dry weight of lettuce produced under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films at a concentration of 10 wt% with different photoluminescence quantum yields in units of grams. S. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films in units of percent. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: Figure4d_f.csv ----------------------------------------- 1. Number of variables: 19 2. Number of cases/rows: 15 3. Variable List A. Name: Outcoupling Efficiency (%) Description: The outcoupling efficiency of the quantum dot film in units of percentage. B. Name: Dry Weight (g) Description: Dry weight of lettuce produced under red-emitting carbon dot (r-CDot) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. C. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under red-emitting carbon dot (r-CDot) quantum dot films in units of percent. D. Name: Dry Weight (g) Description: Dry weight of lettuce produced under green-emitting carbon dot (g-CDot) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. E. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under green-emitting carbon dot (g-CDot) quantum dot films in units of percent. F. Name: Dry Weight (g) Description: Dry weight of lettuce produced under blue-emitting carbon dot (b-CDot) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. G. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under blue-emitting carbon dot (b-CDot) quantum dot films in units of percent. H. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. I. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films in units of percent. J. Name: Dry Weight (g) Description: Dry weight of lettuce produced under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. K. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films in units of percent. L. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper iodide (Cu4I6(pr-ted)2) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. M. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under copper iodide (Cu4I6(pr-ted)2) quantum dot films in units of percent. N. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silicon (Si) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. O. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under silicon (Si) quantum dot films in units of percent. P. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. Q. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films in units of percent. R. Name: Dry Weight (g) Description: Dry weight of lettuce produced under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films at a concentration of 10 wt% with different outcoupling efficiencies in units of grams. S. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films in units of percent. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS1.csv ----------------------------------------- 1. Number of variables: 10 2. Number of cases/rows: 3701 3. Variable List A. Name: Wavelength (nm) Description: Wavelength of light in nanometers B. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of red-emitting carbon dots (r-CDots) quantum dots in inverse meters by weight percent. C. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of green-emitting carbon dots (g-CDots) quantum dots in inverse meters by weight percent. D. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of blue-emitting carbon dots (b-CDots) quantum dots in inverse meters by weight percent. E. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of copper indium sulfied/zinc sulfide (CIS/ZnS) quantum dots in inverse meters by weight percent. F. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dots in inverse meters by weight percent. G. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of copper iodide (Cu4I6(pr-ted)2) quantum dots in inverse meters by weight percent. H. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of silicon (Si) quantum dots in inverse meters by weight percent. I. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dots in inverse meters by weight percent. J. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of indium phosphide/zinc selenide (InP/ZnSe) quantum dots in inverse meters by weight percent. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS2.csv ----------------------------------------- 1. Number of variables: 3 2. Number of cases/rows: 17 3. Variable List A. Name: Wavelength (nm) Description: Wavelength of light in nanometers. B. Name: Absorptance (a.u.) Description: Absorptance of lettuce leaves in arbitrary units. C. Name: Relative Quantum Yield (a.u.) Description: Relative quantum yield of lettuce leaves in arbitrary units. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS3.csv ----------------------------------------- 1. Number of variables: 6 2. Number of cases/rows: 456 3. Variable List A. Name: Time (days) Description: Growing time for lettuce in units of days B. Name: Simulated Solar High eDLI Dry Weight (g) Description: Simulated dry weight of lettuce under a control film (standard sunlight) with a high light intensity in units of grams. C. Name: Simulated Solar Reduced eDLI Dry Weight (g) Description: Simulated dry weight of lettuce under a control film (standard sunlight) with a reduced light intensity in units of grams. D. Name: Simulated CIS/ZnS Dry Weight (g) Description: Simulated dry weight of lettuce under a copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot film in units of grams. E. Name: Experimental Solar Dry Weight (g) Description: Experimentally reported dry weight of lettuce grown under a control film (standard sunlight) at the end of the 19-day growing cycle in units of grams. F. Name: Experimental CIS/ZnS Dry Weight (g) Description: Experimentally reported dry weight of lettuce grown under a copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot film at the end of the 19-day growing cycle in units of grams. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS4.csv ----------------------------------------- 1. Number of variables: 10 2. Number of cases/rows: 100 3. Variable List A. Name: Concentration (wt%) Description: Concentration of the quantum dots in the spectral shifting film in units of weight percent. B. Name: Dry Weight (g) Description: Dry weight of lettuce produced under red-emitting carbon dot (r-CDot) quantum dot films at different concentrations in units of grams. C. Name: Dry Weight (g) Description: Dry weight of lettuce produced under green-emitting carbon dot (g-CDot) quantum dot films at different concentrations in units of grams. D. Name: Dry Weight (g) Description: Dry weight of lettuce produced under blue-emitting carbon dot (b-CDot) quantum dot films at different concentrations in units of grams. E. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films at different concentrations in units of grams. F. Name: Dry Weight (g) Description: Dry weight of lettuce produced under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films at different concentrations in units of grams. G. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper iodide (Cu4I6(pr-ted)2) quantum dot films at different concentrations in units of grams. H. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silicon (Si) quantum dot films at different concentrations in units of grams. I. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films at different concentrations in units of grams. J. Name: Dry Weight (g) Description: Dry weight of lettuce produced under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films at different concentrations in units of grams. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS5.csv ----------------------------------------- 1. Number of variables: 17 2. Number of cases/rows: 3701 3. Variable List A. Name: Wavelength (nm) Description: Wavelength of light in nanometers B. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of cesium lead (bromide iodide) (CsPb(Br2I8)0.3) quantum dots in inverse meters by weight percent. C. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of cesium lead (bromide iodide) (CsPb(Br2I8)0.3) quantum dots normalized to 1 in arbitrary units. D. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of cesium lead bromide (CsPbBr3) quantum dots in inverse meters by weight percent. E. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of cesium lead bromide (CsPbBr3) quantum dots normalized to 1 in arbitrary units. F. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of lead sulfide/cadmium sulfide (PbS/CdS) quantum dots in inverse meters by weight percent. G. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of lead sulfide/cadmium sulfide (PbS/CdS) quantum dots normalized to 1 in arbitrary units. H. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of cadmium selenide/cadmium sulfide (CdSe/CdS) quantum dots in inverse meters by weight percent. I. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of cadmium selenide/cadmium sulfide (CdSe/CdS) quantum dots normalized to 1 in arbitrary units. J. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of cadmium selenide/cadmium zinc sulfide (CdSe/Cd0.6Zn0.4S) quantum dots in inverse meters by weight percent. K. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of cadmium selenide/cadmium zinc sulfide (CdSe/Cd0.6Zn0.4S) quantum dots normalized to 1 in arbitrary units. L. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of manganese-doped cadmium zinc sulfide (Mn2+Cd0.5Zn0.5S) quantum dots in inverse meters by weight percent. M. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of manganese-doped cadmium zinc sulfide (Mn2+Cd0.5Zn0.5S) quantum dots normalized to 1 in arbitrary units. N. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of copper indium sulfide/cadmium sulfide (CIS/CdS) quantum dots in inverse meters by weight percent. O. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of copper indium sulfide/cadmium sulfide (CIS/CdS) quantum dots normalized to 1 in arbitrary units. P. Name: Absorption Coefficient (m^{-1} wt%^{-1}) Description: Absorption coefficient of cadmium selenide/zinc sulfide (CdSe/ZnS) quantum dots in inverse meters by weight percent. Q. Name: Normalized Photoluminescence Intensity (a.u.) Description: Photoluminescence intensity of cadmium selenide/zinc sulfide (CdSe/ZnS) quantum dots normalized to 1 in arbitrary units. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS6.csv ----------------------------------------- 1. Number of variables: 25 2. Number of cases/rows: 100 3. Variable List A. Name: Concentration (wt%) Description: Concentration of the quantum dots in the spectral shifting film in units of weight percent. B. Name: Dry Weight (g) Description: Dry weight of lettuce produced under cesium lead (bromide iodide) (CsPb(Br2I8)0.3) quantum dot films at different concentrations in units of grams. C. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under cesium lead (bromide iodide) (CsPb(Br2I8)0.3) quantum dot films in units of percent. D. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement cesium lead (bromide iodide) (CsPb(Br2I8)0.3) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. E. Name: Dry Weight (g) Description: Dry weight of lettuce produced under cesium lead bromide (CsPbBr3) quantum dot films at different concentrations in units of grams. F. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under cesium lead bromide (CsPbBr3) quantum dot films in units of percent. G. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement cesium lead bromide (CsPbBr3) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. H. Name: Dry Weight (g) Description: Dry weight of lettuce produced under lead sulfide/cadmium sulfide (PbS/CdS) quantum dot films at different concentrations in units of grams. I. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (12.5 g) and lettuce grown under lead sulfide/cadmium sulfide (PbS/CdS) quantum dot films in units of percent. J. Name: Required Outdoor eDLI (mol/m^2/day) Description: Required outdoor extended daily light integral (eDLI) to implement lead sulfide/cadmium sulfide (PbS/CdS) quantum dot films for a transmitted eDLI of 20 in units of mol/m^2/day. K. Name: Dry Weight (g) Description: Dry weight of lettuce produced under cadmium selenide/cadmium sulfide (CdSe/CdS) quantum dot films at different concentrations in units of grams. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS7.csv ----------------------------------------- 1. Number of variables: 37 2. Number of cases/rows: 100 3. Variable List A. Name: Concentration (wt%) Description: Concentration of the quantum dots in the spectral shifting film in units of weight percent. B. Name: Dry Weight (g) Description: Dry weight of lettuce produced under red-emitting carbon dot (r-CDots) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. C. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under red-emitting carbon dot (r-CDots) quantum dot films in units of percent. D. Name: Dry Weight (g) Description: Dry weight of lettuce produced under red-emitting carbon dot (r-CDots) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. E. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under red-emitting carbon dot (r-CDots) quantum dot films in units of percent. F. Name: Dry Weight (g) Description: Dry weight of lettuce produced under green-emitting carbon dot (g-CDots) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. G. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under green-emitting carbon dot (g-CDots) quantum dot films in units of percent. H. Name: Dry Weight (g) Description: Dry weight of lettuce produced under green-emitting carbon dot (g-CDots) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. I. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under green-emitting carbon dot (g-CDots) quantum dot films in units of percent. J. Name: Dry Weight (g) Description: Dry weight of lettuce produced under blue-emitting carbon dot (b-CDots) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. K. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under blue-emitting carbon dot (b-CDots) quantum dot films in units of percent. L. Name: Dry Weight (g) Description: Dry weight of lettuce produced under blue-emitting carbon dot (b-CDots) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. M. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under blue-emitting carbon dot (b-CDots) quantum dot films in units of percent. N. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. O. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films in units of percent. P. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. Q. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under copper indium sulfide/zinc sulfide (CIS/ZnS) quantum dot films in units of percent. R. Name: Dry Weight (g) Description: Dry weight of lettuce produced under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. S. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films in units of percent. T. Name: Dry Weight (g) Description: Dry weight of lettuce produced under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. U. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under manganese zinc selenide/zinc sulfide (MnZnSe/ZnS) quantum dot films in units of percent. V. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper iodide (Cu4I6(pr-ted)2) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. W. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under copper iodide (Cu4I6(pr-ted)2) quantum dot films in units of percent. X. Name: Dry Weight (g) Description: Dry weight of lettuce produced under copper iodide (Cu4I6(pr-ted)2) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. Y. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under copper iodide (Cu4I6(pr-ted)2) quantum dot films in units of percent. Z. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silicon (Si) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. AA. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under silicon (Si) quantum dot films in units of percent. AB. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silicon (Si) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. AC. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under silicon (Si) quantum dot films in units of percent. AD. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. AE. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films in units of percent. AF. Name: Dry Weight (g) Description: Dry weight of lettuce produced under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. AG. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under silver indium sulfide/zinc sulfide (AgInS2/ZnS) quantum dot films in units of percent. AH. Name: Dry Weight (g) Description: Dry weight of lettuce produced under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films at different concentrations under 5 mol/m^2/day extended daily light integral in units of grams. AI. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (0.63 g) and lettuce grown under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films in units of percent. AJ. Name: Dry Weight (g) Description: Dry weight of lettuce produced under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films at different concentrations under 10 mol/m^2/day extended daily light integral in units of grams. AK. Name: Dry Weight Difference (%) Description: Difference in dry weight between lettuce grown under the standard solar spectrum (5.2 g) and lettuce grown under indium phosphide/zinc selenide (InP/ZnSe) quantum dot films in units of percent. ----------------------------------------- DATA-SPECIFIC INFORMATION FOR: FigureS8.csv ----------------------------------------- 1. Number of variables: 15 2. Number of cases/rows: 441 3. Variable List A. Name: Blue Fraction (-) Description: Unitless fraction of transmitted blue light. B. Name: Green Fraction (-) Description: Unitless fraction of transmitted green light. C. Name: Red Fraction (-) Description: Unitless fraction of transmitted red light. D. Name: Far-red Fraction (-) Description: Unitless fraction of transmitted far-red light. E. Name: Quantum Use Efficiency (g/J) Description: Quantum use efficiency of the lettuce plant under no transmitted blue light in units of grams per joule. F. Name: Blue Fraction (-) Description: Unitless fraction of transmitted blue light. G. Name: Green Fraction (-) Description: Unitless fraction of transmitted green light. H. Name: Red Fraction (-) Description: Unitless fraction of transmitted red light. I. Name: Far-red Fraction (-) Description: Unitless fraction of transmitted far-red light. J. Name: Quantum Use Efficiency (g/J) Description: Quantum use efficiency of the lettuce plant under no transmitted green light in units of grams per joule. K. Name: Blue Fraction (-) Description: Unitless fraction of transmitted blue light. L. Name: Green Fraction (-) Description: Unitless fraction of transmitted green light. M. Name: Red Fraction (-) Description: Unitless fraction of transmitted red light. N. Name: Far-red Fraction (-) Description: Unitless fraction of transmitted far-red light. O. Name: Quantum Use Efficiency (g/J) Description: Quantum use efficiency of the lettuce plant under no transmitted far-red light in units of grams per joule.