New Smart Windows: "Tunable" Window Tintings


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Technology developed by the University of Cincinnati and industry partners can do something that neither blinds nor existing smart windows can do. This patent-pending research, supported by the National Science Foundation, will lead to low-cost window tintings which dynamically adapt for brightness, color temperatures and opacity (to provide for privacy while allowing light in).

Technology developed by the University of Cincinnati and industry partners can do something that neither blinds nor existing smart windows can do. This patent-pending research, supported by the National Science Foundation, will lead to low-cost window tintings which dynamically adapt for brightness, color temperatures and opacity (to provide for privacy while allowing light in).

Take some time to see the renderings by UC's Tim Zarki of what the dynamic, low-cost window tintings  will be able to achieve.

A partnership between the University of Cincinnati, Hewlett Packard, and EMD/Merck Research Labs has resulted in a patent-pending breakthrough in 'tunable' window tintings. The breakthrough means traditional window shades could soon be replaced by a low-cost tinting where the brightness, color temperature (warm or cool just like incandescent light bulbs) and opacity (privacy) are adjustable by the user.

Details on this research, partly funded by the National Science Foundation, are in the June issue of the prestigious trade journal, “Applied Optics.”

Rendering of a window tinting setting.

Rendering of the effect of the warm color setting for sunlight transmission by means of the UC-developed 'tunable' window tintings.

The research was led by Sayantika Mukherjee, doctoral student in UC’s Novel Devices Laboratory, part of the university’s College of Engineering and Applied Science, and by W.L. Hsieh, visiting doctoral student from the Institute of Applied Mechanics, National Taiwan University; N. Smith, scientist at Merck Chemicals, Ltd.; M. Goulding, scientist at Merck Chemicals, Ltd.; and Jason Heikenfeld, UC professor of electrical engineering and computing systems.

Importantly, the newly developed device structure that makes these “smart windows” possible is very simple to manufacture, allowing affordability for both business and home use. It can be integrated into new windows or even easily applied to already existing windows, by means of a roll-on coating consisting of a honeycomb of electrodes.

Benefits of the New Smart Windows

Currently, most home and commercial windows use mechanical shades to provide privacy and to block light, heat or cold. This centuries-old technology is already inexpensive and effective, which has slowed the adoption of electronically controlled window tinting, which previously could only mimic the clear-to-opaque performance of mechanical shades. However, this new breakthrough at the University of Cincinnati is about to change that.

States UC’s Jason Heikenfeld, “Simple electronic window switching is not enough. You need to provide consumers with something you can’t do mechanically, and for which there is already a large demand. For example, there is already proven demand for control of color temperature in the lightbulb market, and after all, windows are a source of lighting. Maybe even more compelling, go home to your neighborhood and look at the drawn blinds for privacy but which also block sunlight. What if you could have your privacy and also let the light in at any brightness you want?” 

So, in other words, shade and privacy can be simultaneously, electronically controlled for the first time. Windows could go milky for privacy so no one can see in, but still allow 90 percent (or more) of the available light in. Or, a setting change could dim the entering light or change the color of the light along a spectrum from cooler blue to warmer yellow. “Blinds can’t do that,” said UC’s Mukherjee.

So, in summary, the new UC-developed Smart Window device structure provides options for doing any one of the following: 

Be adjusted simultaneously for brightness and color temperature much like consumers can today buy lightbulbs that provide a warm or a cool light. This will affect the quality of the light entering a home or building.

Allow you to have your privacy while letting 90 percent or more of the light in or dim the entering light to a lower volume, or revert back to a fully clear window. No more need to block natural light entering the house just for the sake of a little privacy.

Provide multidimensional control of a greater range of color and opacity selections. Beyond the above two examples, simultaneous control between any other types of two window states are possible. For example, a window could also independently control both visible light and infrared heat transmission. So, you could block infrared heat from the sun in the summer but let it into the house in the winter.

Importantly, all of this is inexpensive to manufacture and can be applied to  windows during standard manufacturing. The new device structure can also be applied to windows currently in use, via a cut-to-size film of electrodes applied to windows already in place in homes and other buildings.

The Technology Behind the Breakthrough

Heikenfeld and UC’s Novel Devices Laboratory are international leaders in developments related to adaptive optics, e-paper and the use of color in displays on electronic devices. For years, they have made breakthroughs related to the brightness, color saturation and speed of such displays.

The challenge for the UC, Merck and HP team consisted of applying this technology, common in e-paper electronic displays on our mobile and computer devices, to a larger surface like windows and to do so in a way that could be manufactured inexpensively, for less than the $30 per square foot, which is the industry standard for window manufacturing. It’s a challenge the team has worked on for the past three years thanks to in-kind support from all three partners and to a $357,526 grant from the National Science Foundation’s Grant Opportunities for Academic Liaison with Industry program.

Explains Mukherjee, “Basically, one color has one charge. Another color has another charge, and we apply voltage to repel or attract the colors into different positions. The basic technology is not that different from what our group has previously demonstrated before in electronic display devices. The greater challenge was to find an appropriate device structure in order to apply the technology to the larger surface area of a window in a way that was inexpensive and fairly easy. The greater impact for us was to realize the potential of a few selective but compelling operating modes such as changing color temperature or privacy/shade.” 

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