Presentation is loading. Please wait.

Presentation is loading. Please wait.

Eklund, M. J. , A. K. Aase, and C. J. Bell. 2018

Published byἈβραάμ Μακρής Modified over 5 years ago

Similar presentations

Presentation on theme: "Eklund, M. J. , A. K. Aase, and C. J. Bell. 2018"— Presentation transcript:

1 Eklund, M. J. , A. K. Aase, and C. J. Bell. 2018
Eklund, M. J., A. K. Aase, and C. J. Bell Progressive Photonics: Methods and applications of sequential imaging using visible and non-visible spectra to enhance data-yield and facilitate forensic interpretation of fossils. Journal of Paleontological Techniques 20: 1-36. Figure 4: Calcite from the Challenger Cave in Mexico (TMM ). Images are in A) visible light, yielding off-white color; B) UVA 368 nm wavelength, yielding a fuchsia color; C) UVB 315 nm wavelength yielding a pastel yellow color; D) UVC 254 nm wavelength, yielding a mid-range blue color; E) Combined UVABC radiation yielding a washed-out blue-grey-violet color. The latter reaction cannot be attributed in whole or in part to any particular wavelength, but it is clear that the three wavelengths in combination generate unique visualizations. In our experience, there is no good example of combined UVABC yielding a novel insight on a fossil specimen, but the mineral example shown here demonstrates the possibility. The imaging cube is rotated in each image to document wavelength. Beneath the cube is a card confirming that the camera is imaging full color range in each image, despite differential reaction of the specimen; the card behaves in nearly the same way under each wavelength, demonstrating that the difference in each image is a result of differential fluorescence of the specimen. Lower imaging plate is a pico color calibration target, with full spectrum color return only in visible light.

2 4A visible light

3 4B UVA 368nm

4 4C UVB 315nm

5 4D UVC 254nm

6 4E UVA+B+C

Download ppt "Eklund, M. J. , A. K. Aase, and C. J. Bell. 2018"

Similar presentations

Electromagnetic Radiation

Electromagnetic Radiation
Capturing Light Energy and the Electromagnetic Spectrum.

Capturing Light Energy and the Electromagnetic Spectrum.
Light, Photon Energies, and Atomic Spectra

Light, Photon Energies, and Atomic Spectra
Avoiding bleed-through artifacts on the confocal microscope Fluorescent dyes are molecules that, when exposed to light of a specific range of wavelengths,

Avoiding bleed-through artifacts on the confocal microscope Fluorescent dyes are molecules that, when exposed to light of a specific range of wavelengths,
Wavelength, Frequency, and Energy Practice Problems

Wavelength, Frequency, and Energy Practice Problems
Life always offers you a second chance. It’s called tomorrow.

Life always offers you a second chance. It’s called tomorrow.
Fig. 33-11 Wave front at a time dt after passing thru a stationary plane © 2003 J. F. Becker San Jose State University Physics 52 Heat and Optics.

Fig Wave front at a time dt after passing thru a stationary plane © 2003 J. F. Becker San Jose State University Physics 52 Heat and Optics.
Physics 52 - Heat and Optics Dr. Joseph F. Becker Physics Department San Jose State University © 2005 J. F. Becker.

Physics 52 - Heat and Optics Dr. Joseph F. Becker Physics Department San Jose State University © 2005 J. F. Becker.
4/19/06 Spectra: Continuous vs. Discrete Friday’s Reading: Section 14.3: Lasers and LEDs (pp. 464 – 470) Upcoming Reading Assignments: Section 15.1: Cameras.

4/19/06 Spectra: Continuous vs. Discrete Friday’s Reading: Section 14.3: Lasers and LEDs (pp. 464 – 470) Upcoming Reading Assignments: Section 15.1: Cameras.
Light, Photon Energies, and Atomic Spectra

Light, Photon Energies, and Atomic Spectra
Electricity, Sound and Light Chapter Ten: Light and Color 10.1 Properties of Light 10.2 Color and Vision 10.3 Optics.

Electricity, Sound and Light Chapter Ten: Light and Color 10.1 Properties of Light 10.2 Color and Vision 10.3 Optics.
Warm Up Draw the Bohr Model for Aluminum and Neon.

Warm Up Draw the Bohr Model for Aluminum and Neon.
Emission Spectra Bohr Model of the Atom.

Emission Spectra Bohr Model of the Atom.
Electron Energy and Radiation Quantum Mechanics and Electron Movement.

Electron Energy and Radiation Quantum Mechanics and Electron Movement.
Unit 6: Electrons in Atoms part 1: properties of waves.

Unit 6: Electrons in Atoms part 1: properties of waves.
What title would you give to each droodle?. Almost bald man with a split-end.

What title would you give to each droodle?. Almost bald man with a split-end.
Light and Color Speed, Wavelength, Color And Human Perception.

Light and Color Speed, Wavelength, Color And Human Perception.
The Electro-Magnetic Spectrum. Light Properties  Have properties of waves… Crests & troughsCrests & troughs Reflect & refract (bend)Reflect & refract.

The Electro-Magnetic Spectrum. Light Properties  Have properties of waves… Crests & troughsCrests & troughs Reflect & refract (bend)Reflect & refract.
Electromagnetic Radiation (NB Pgs 7-9 odd) Picture pg 8.

Electromagnetic Radiation (NB Pgs 7-9 odd) Picture pg 8.
Brain pop.

Brain pop.

Similar presentations

Ads by Google