Light polarization creates art, explains mathematical concepts – Phys.org | Candle Made Easy

Stochastic stress-induced birefringence in plastic spoons left in the hot sun is visualized by polarization-filtered staining. The spoons are placed in an open-gate arrangement between a pair of coaligned polarizer sheets, with a parchment paper backing serving as a diffuser for the sunlight illumination. Photo credit: Aaron Slepkov, University of Trent

The polarization of light underpins a variety of new technological innovations, including 3D cinema and LCDs. In LCDs, tiny electronically controllable liquid crystal elements are embedded between polarizers. If instead other transparent polarization-changing films – such as cellophane wrapping paper and packaging tape – are placed between a series of polarizers, a range of polarization-filtered colors can be observed.

In which American Journal of PhysicsAaron Slepkov, of Trent University in Canada, studies the physics of how such colors are formed, how they can be controlled, and why subtle changes in viewing angle, sample orientation, and the order of film layers between polarizers can have a dramatic effect on the observed colors.

The research emphasizes visual examples of concepts related to birefringence, such as addition, subtraction, and order of operations. For example, the non-commutative nature of birefringent addition is typically illustrated using formal matrix mathematics. In this case, however, the researchers use color visualization.

“I use a visual color language to illustrate subtle physics that are often only demonstrated mathematically,” Slepkov said.

He was inspired in part by the work of artist Austine Wood Comarow, who made a career of applying polarized filtered color techniques to fine art. Austine coined the term “polage” or polarization of collage to refer to her art.

Austine created a wide range of work using intricate layers of cut cellophane and other birefringent polymer films interspersed with layers of film polarizers. Her pieces range from small, one-off pieces that fit on a shelf to massive, career-spanning installations at institutions such as Disney Epcot Center in 1981 and Gyeongsangnam-do Institute of Science Education in Jinju, South Korea in 2017.

“In this work I clarify the connection between polarization filtering and the observed colors. I show how different aspects of birefringence in ordinary household films provide opportunities and challenges for their use in art,” Slepkov said.

To produce polarization-filtered color, all that is needed is a birefringent sample placed between polarizers that form a polarization gate. Many household items can offer a kaleidoscopic range of colors and patterns.

For example, transparent plastic cutlery provides a classic demonstration where localized stress in the polymer structure results in differential birefringence, observable through a polarization gate. Likewise, somewhat haphazardly folded kitchen wrap, gift basket wrap, and layered tape can form intricate images reminiscent of stained glass windows.

“Manipulating birefringent film to create color images is fun and intellectually stimulating. Much of the nuanced physics of polarization, birefringence, retardation, and color theory can be observed in this accessible but far-reaching endeavor,” Slepkov said.


Highest degree of purity for polarized X-rays


More information:
Aaron D. Slepkov, Painting in Polarization, American Journal of Physics (2022). DOI: 10.1119/5.0087800

Provided by the American Institute of Physics

Citation: Light Polarization Creates Art, Explains Mathematical Concepts (2022 July 22) Retrieved July 22, 2022 from https://phys.org/news/2022-07-polarization-art-mathematical-concepts.html

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