Methods and Apparatus for Transparent Display Using Up-Converting Nanoparticles

Technology #16097

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FIG. 1 shows a back-lit transparent display with nanoparticles that upconvert incident infrared light via a nonlinear frequency-doubling interaction.FIG. 2 shows a back-lit transparent display with nanoparticles that upconvert incident infrared light via a nonlinear sum-frequency interaction.FIG. 3 shows an edge-lit transparent display with nanoparticles that upconvert incident infrared light via a nonlinear sum-frequency interaction.FIG. 4 shows a three-dimensional transparent display made with upconverting nanoparticles circulated within a cavity using a circulation system. FIG. 5A shows an energy level diagram of a frequency-doubling nanoparticle suitable for use in the transparent display of FIG. 1.  FIG. 5B shows an energy level diagram of a frequency-summing nanoparticle suitable for use in the transparent displays of FIGS. 2 and 3.FIG. 6A illustrates a process for making a transparent screen with upconverting nanoparticles.FIGS. 6B and 6C are flowcharts that illustrate different processes for making transparent screens with upconverting nanoparticles.
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Inventors
Professor Marin Soljacic
Department of Physics, MIT
External Link (www.mit.edu)
Ofer Shapira
Research Laboratory of Electronics, MIT
Bo Zhen
Research Laboratory of Electronics, MIT
Wenjun Qiu
Department of Physics, MIT
Chia Wei Hsu
Department of Physics, MIT
Managed By
Dave Sossen
MIT Technology Licensing Officer
Patent Protection

Methods and apparatus for transparent display using up-converting nanoparticles

US Patent 9,458,989

Applications

Three-dimensional transparent displays in medicine, engineering, scientific research and development, oil and gas extraction, and entertainment.

Technology

This technology consists of transparent color displays with nanoparticles made with nonlinear materials and is designed to exhibit optical resonances. These nanoparticles are embedded in a transparent substrate, such as a flexible piece of clear plastic or acrylic. Illuminating the nanoparticles with invisible light (e.g., infrared or ultraviolet light) causes them to emit visible light in a desired pattern.

Problem Addressed

A number of transparent display technologies exist, but none have gained widespread usage. By eliminating the backlight of a liquid crystal display (LCD), the transparency is increased, but only up to a transmittance of about 15%. An organic light-emitting diode (OLED) can also be made transparent, but OLED production remains costly and OLED transmittance is also limited (typically less than 40%). Electroluminescent displays have also been made transparent; however,  they have been limited to single colors. Recently, fluorescent films have been combined with ultraviolet (UV) lights to make multi-colored displays that are transparent; yet, intense UV sources are required due to the small emission cross sections of the fluorescent particles.

There has also been progress in 3D transparent displays, but such technologies have remained either in the lab or in specialized facilities. Technologies based on revolving 2D displays suffer from image flickering. Stacking several 2D displays yields a quasi-3D display with a limited viewing angle that cannot provide true 3D image depth. At least one prototype of a volumetric 3D laser display has also been demonstrated, but it was a miniature device, and its production is very difficult to scale. To date, none of these technologies has yielded a 3D display that is practical enough for consumer use.


Advantages

  • Display true volumetric 3D images without special eyeglasses
  • Scalable to large display sizes