If You Give Me A Task With No Deadline I Will Literally Never Do It But If You Give Me A Deadline I Will

In this video, mixtures of inks (likely printer toners) and fluids move and swirl. Magnetic fields contort the ferrofluidic ink and make it dance, while less viscous fluids spread into their surroundings via finger-like protuberances. (Video credit and submission: Antoine Delach)

Introducing the most versatile piece of laboratory equipment: the septum. It’s a septum! It’s a makeshift SureSeal! It’s a makeshift vial adapter! It’s a holder for reaction tubes!

Chemist screws up:

Your lungs are now filled with hydrogen cyanide

Day 2 of our mushroom lab: running our sample through a DEAE-Sepharose column

Reverse psychology that's not in psychology. Reverse biology...?

How did you decide to do a project with RNA?

I was having a conversation with someone in our department about how useful and cheap next-gen sequencing is, and how I was considering spending out my grant on a project looking at immune gene expression in spiders. He told me flat out that I wasn’t capable of doing it, because I wouldn’t understand it enough to ever publish. So I used a kit to extract RNA, sent off the samples, read a few books in the meantime, learned to code, wrote the scripts for R and the supercomputer, then did it. I’m writing it up now, and have found some pretty cool stuff! I’m glad I learned it too, since it’s a good skill to have.

TL;DR: some asshole told me I couldn’t do it, so I decided to do it.

Gases +  Electric Field 

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Source

girl help im trapped in resin

Jane Goodall teaches John Oliver how to fight, eat bananas like a chimpanzee

Planet Saturn, observed by the Cassini space probe on March 16, 2016.

Atomization is the process of breaking a liquid into a spray of fine droplets. There are many methods to accomplish this, including jet impingement, pressure-driven nozzles, and ultrasonic excitement. In the images above, a drop has been atomized through vibration of the surface on which it rests. Check out the full video. As the amplitude of the surface’s vibration increases, the droplet shifts from rippling capillary waves to ejecting tiny droplets. With the right vibrational forcing, the entire droplet bursts into a fine spray, as seen in the photo above. The process is extremely quick, taking less than 0.4 seconds to atomize a 0.1 ml drop of water. (Photo and video credit: B. Vukasinovic et al.; source video)