An instrument design for non-contact detection of biomolecules and minerals on Mars using fluorescence

Smith, H. D.; McKay, Christopher P.; Duncan, A.; Sims, Ronald C.; Anderson, Anne J.; Grossl, Paul R.

doi:10.1186/1754-1611-8-16

Cited by 16 publications

(10 citation statements)

References 32 publications

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“…The results obtained for pyrene are in good agreement with experimental measurements. 51,52 It is worth noting that the anisotropic behaviour of the optical properties of QDs observed in ref. 39 and 49 disappear under the edges functionalization with OH, CH 3 and COOH.…”

Section: Optical Propertiesmentioning

confidence: 94%

Graphene and silicene quantum dots for nanomedical diagnostics

et al. 2020

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Section: Optical Propertiesmentioning

confidence: 94%

Graphene and silicene quantum dots for nanomedical diagnostics

et al. 2020

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“…However, fluorescence emission below ∼700 nm was not observed in samples when exited in the spectral ranges used here, i.e., 450–492 nm and 515–560 nm (Smith et al . ), and interferences between carbonate and photopigment fluorescence were thus not observed. Obvious ‘false signal’ due to reflectances from the aquarium glass and metal stands holding the ikaite column in place, were deleted from the original Canon RAW fluorescence images recorded under blue and green excitation.…”

Section: Methodsmentioning

confidence: 99%

Phototrophic microbes form endolithic biofilms in ikaite tufa columns (SW Greenland)

Trampe

Castenholz

Larsen

et al. 2017

Environmental Microbiology

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Marine tufa-columns, formed by the hydrated carbonate mineral ikaite, present a unique alkaline microbial habitat only found in Ikka Fjord (SW-Greenland). The outermost parts of the ikaite columns exhibit a multitude of physico-chemical gradients, and the porous ikaite is colonized by endolithic phototrophic biofilms serving as a substrate for grazing epifauna, where scraping by sea urchins affects overall column-topography. We present a detailed study of the optical microenvironment, spatial organization, and photosynthetic activity of endolithic phototrophs within the porous ikaite crystal matrix. Cyanobacteria and diatoms formed distinctly coloured zones and were closely associated with ikaite-crystals via excretion of exopolymers. Scalar-irradiance measurements showed strong attenuation of visible light (400-700 nm), where only ∼1% of incident irradiance remained at 20 mm depth. Transmission spectra showed in vivo absorption signatures of diatom and cyanobacterial photopigments, which were confirmed by HPLC-analysis. Variable-chlorophyll-fluorescence-imaging showed active photosynthesis with high-light acclimation in the outer diatom layer, and low-light acclimation in the underlying cyanobacterial part. Phototrophs in ikaite thus thrive in polymer-bound endolithic biofilms in a complex gradient microhabitat experiencing constant slow percolation of highly alkaline phosphate-enriched spring water mixing with cold seawater at the tufa-column-apex. We discuss the potential role of these biofilms in ikaite column formation.

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“…The rapidly approaching Mars 2020 mission brings about a crucial need to better understand the capabilities of Raman and fluorescence instruments to identify biosignatures in realistic, natural, and complex Mars analog samples. Recent work has demonstrated the capabilities of UV Raman and fluorescence instruments for biosignature detection on Mars (e.g., Smith et al, 2014), including those that form the foundation of the SHERLOC instrument (Beegle et al, 2014(Beegle et al, , 2015(Beegle et al, , 2016Abbey et al, 2017) and the foundation of the UV system used here (Eshelman et al, 2014(Eshelman et al, , 2015Skulinova et al, 2014). However, these previous studies investigated synthetic, pure, or extracted and concentrated organics, or mineral powders spiked with organic molecules, and they do not take into account complex interactions of mixed-phase, fossilized organics interacting with their host matrix, as found in nature.…”

Section: Objectives Of This Studymentioning

confidence: 99%

Detecting Kerogen as a Biosignature Using Colocated UV Time-Gated Raman and Fluorescence Spectroscopy

et al. 2018

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The Mars 2020 mission will analyze samples in situ and identify any that could have preserved biosignatures in ancient habitable environments for later return to Earth. Highest priority targeted samples include aqueously formed sedimentary lithologies. On Earth, such lithologies can contain fossil biosignatures as aromatic carbon (kerogen). In this study, we analyzed nonextracted kerogen in a diverse suite of natural, complex samples using colocated UV excitation (266 nm) time-gated (UV-TG) Raman and laser-induced fluorescence spectroscopies. We interrogated kerogen and its host matrix in samples to (1) explore the capabilities of UV-TG Raman and fluorescence spectroscopies for detecting kerogen in high-priority targets in the search for possible biosignatures on Mars; (2) assess the effectiveness of time gating and UV laser wavelength in reducing fluorescence in Raman spectra; and (3) identify sample-specific issues that could challenge rover-based identifications of kerogen using UV-TG Raman spectroscopy. We found that ungated UV Raman spectroscopy is suited to identify diagnostic kerogen Raman bands without interfering fluorescence and that UV fluorescence spectroscopy is suited to identify kerogen. These results highlight the value of combining colocated Raman and fluorescence spectroscopies, similar to those obtainable by SHERLOC on Mars 2020, to strengthen the confidence of kerogen detection as a potential biosignature in complex natural samples. Key Words: Raman spectroscopy-Laser-induced fluorescence spectroscopy-Mars Sample Return-Mars 2020 mission-Kerogen-Biosignatures. Astrobiology 18, 431-453.

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An instrument design for non-contact detection of biomolecules and minerals on Mars using fluorescence

Cited by 16 publications

References 32 publications

Graphene and silicene quantum dots for nanomedical diagnostics

Graphene and silicene quantum dots for nanomedical diagnostics

Phototrophic microbes form endolithic biofilms in ikaite tufa columns (SW Greenland)

Detecting Kerogen as a Biosignature Using Colocated UV Time-Gated Raman and Fluorescence Spectroscopy

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