Inspired by the iconic Rings of Saturn and images from NASA's Cassini Solstice, this dress encapsulates the mesmerizing curves of everyone's favorite planet.
This dress looks great and fits great. The black panels at the sides give a nice silhouette. It draws a lot of compliments! Highly recommended.
Not only is this dress well-crafted and very comfortable, but it is also a show-stopper. It pays tribute to an iconic space exploration mission and also shows that there truly is no boundary between science and art. I recently wore it to a commercial space industry networking event and so many people wanted to know where I got it - and of course I told them, because wearable art like this deserves to be shared.
This dress is fabulous! It's comfortable, fits well, and is perfect for work or for play.
Great fit and so comfortable! I've gotten several compliments on the fit and the design. I really love this dress!
This is my favorite dress. I'm already planning which shenova dress I'm going to buy next.
Math + Fashion go quite well together! This mathematically fashionable dress is calculated to be fabulously figure flattering. The next number is found by adding up the two numbers before it. When we make squares with those widths, we get a nice spiral...It is that simple!
What's your fashion element?
Shake up your wardrobe with this chemistry-chic dress, inspired by Yves Saint Laurent's famous "Mondrian Dress". Features the Periodic Table on both front and back.
Want to wear the fabric of space time?
Celebrate the discovery of gravitational waves with this smart casual look. At first glance, you see plaid. Look a bit further and- surprise, you'll recognize the data from the LIGO detectors. It's a classic professional dress with an educational twist.
These plots show the signals of gravitational waves detected by the twin LIGO observatories at Livingston, Louisiana, and Hanford, Washington. The signals came from two merging black holes, each about 30 times the mass of our sun, lying 1.3 billion light-years away.
The top two plots show data received at Livingston and Hanford, along with the predicted shapes for the waveform. These predicted waveforms show what two merging black holes should look like according to the equations of Albert Einstein's general theory of relativity, along with the instrument's ever-present noise. Time is plotted on the X-axis and strain on the Y-axis. Strain represents the fractional amount by which distances are distorted.
As the plots reveal, the LIGO data very closely match Einstein's predictions.
Digitally Printed Material: