Smparticle2 - Untitled

Warrior of the grassland - Anup Deodhar - The Comedy Wildlife.

That Moment… My Heart…

(Photo Credit: Kenneth Jarecke/Contact Press Image)

Entering the house owned by a friend working in the private sector, the grad student anxiously reassesses many of his life choices.

Snowflakes from William Scoresby’s des Jüngern Tagebuch einer reise auf den Wallfischfang, (Hamburg: F. Perthes, 1825), the German translation of Journal of a voyage to the northern whale-fishery.

Scoresby was an Arctic explorer with interests in meteorology and navigation, who led an Arctic exploration in the early 1800s to the area around Greenland.  

“It is the most passionate relationship of the film. It is almost equivalent to that of Scarlett O’hara and Ashley Wilkes and Scarlett and Rhett Butler. Mammy is Scarlett’s true mother. It is Mammy to whom Scarlett goes to for advice, it is Mammy who sees deeply into Scarlett’s emotions and knows everything that’s going on with her. Whereas Scarlett’s biological mother doesn’t understand the emotional turmoil of her daughter. This is an incredible performance, very inflictive, that unfortunately is never getting discussed these days because of the sensitivity we should properly feel.” -Camille Paglia

Your blog is super cool! I have a few questions. How do you get your equipment and chemicals to carry out your experiments? I was just wondering as I'd like to start doing experiments at home. What would be a good experiment to start with also? Sorry if you have already answered these questions

Hey, thanks for the kind words! This is going to be a long answer! Let’s start with equipment:

Keep reading

Building microfluidic circuits is generally a multi-day process, requiring a clean room and specialized manufacturing equipment. A new study suggests a quicker alternative using fluid walls to define the circuit instead of solid ones. The authors refer to their technique as “Freestyle Fluidics”. As seen above, the shape of the circuit is printed in the operating fluid, then covered by a layer of immiscible, transparent fluid. This outer layer help prevent evaporation. Underneath, the circuit holds its shape due to interfacial forces pinning it in place. Those same forces can be used to passively drive flow in the circuit, as shown in the lower animation, where fluid is pumped from one droplet to the other by pressure differences due to curvature. Changing the width of connecting channels can also direct flow in the circuits. This technique offers better biocompatibility than conventional microfluidic circuits, and the authors hope that this, along with simplified manufacturing, will help the technique spread. (Image and research credit: E. Walsh et al., source)