Would you believe me if i said this is theee ACTUAL first time i drew eefan…with face that is.

I started tweaking bc it looks NOTHING like him now that i think…hurm. His drawing is to be reprocessed soon.. @grilde1chesse

Obscure Anime of the Day:

Eat-Man

Aired: 1997

Genres: Action, Adventure, Comedy, Cyberpunk, Drama, Magic, SciFi, Shounen, Superpower, Violence

Five Critical Senses of Engagement by Dr Timothy Eatman adapted by Nick Sousanis

I am legitimately bitter more people don't know about Eat-man

Like come on! This guy is named Bolt Crank and he has the ability to eat anything and then re-create it, whole and fully functional from his arm(as long as he's eaten all of the necessary pieces).

6/23，星期五

畫畫看波特

so i made a couple of eat man edits

By checking my reblogs, I'm so glad to see more people who enjoy #eatman on tumblr.

If you like eatman of course you have my follow! Aand feel free to share your opinions and impressions to me c:

and your love for Bolt Crank of course! ^^

BOLT CRANK ARRHGFGGHHGHHG BOLT CRANK AUGHHGHHGHHH I LOVE YOU BOLT CRANK IM SORRY I FORGOT ABOUT YOU

who the fuck is eatman

making shitposts for a 25 year old show >>>>>

no this is real

Uncharismatic Fact of the Day

The phrase 'busy as a bee' is no joke! It takes about 550 bees visiting over 2 million flowers to make 0.4 kg (1 lb) of honey! In turn, each pound of beeswax needs 7.7-9 kg (17-20 lbs) of honey. On average, each worker only produces 1/12th of a teaspoon of honey (0.5 g) in her lifetime, meaning that thousands of bees must work around the clock to provide enough food and building materials for their hive.

(Image: A Western honey bee (Apis mellifera) collecting nectar by Ross Eatman)

If you like what I do, consider buying me a ko-fi!

Yall is Eatman good?

Second floor, in front of round window at Weatherspoon Art Museum, Greensboro, North Carolina, January 2021. Visitors are allowed to sit on it.

Memorial Bench for Joshua Eatman, 2003.

Michael Joerling (American, b. 1951). Bubinga and maple wood.

Striving for Restorative Justice and Repair in Academe - Timothy Eatman

Eatman: I wish you luck in locating a more bizarre game than this one

LANDOVER, Md. At halftime, this reenactment was tied 3-3. The rating used to be 13-9 at the six-minute mark of the fourth quarter. More details

To boost supply chains scientists are looking at ways to recover valuable materials from water

Promoting national security and economic competitiveness will require America’s researchers to find new ways to obtain the materials that we need for many technologies. These include batteries, magnets in electric motors, catalysts, nuclear reactors and other essential carbon-free energy technologies. Water represents one underexplored avenue of acquiring these materials. Scientists at the U.S. Department of Energy’s Argonne National Laboratory have recently published a comprehensive review detailing the various mechanisms by which critical materials can be extracted from diverse water streams. Different types of water offer different kinds of material resources, said Seth Darling, chief science and technology officer for Argonne’s Advanced Energy Technologies directorate. ​”The oceans are such a tremendous resource because the total quantities of many valuable and important materials are vast, but they are also highly dilute,” he said. ​”Wastewater has also been in need of reframing — we want people to see that wastewater is not truly waste, rather, it’s rich with all sorts of valuable stuff.” Darling also pointed to groundwater aquifers and geothermal brines as other possible sources of valuable materials. These materials include lithium, which is increasingly in demand for electric vehicle batteries and could be used to help decarbonize our economy. ​”Lithium is in the ocean and in geothermal brines; you’d extract it differently from these two sources but it’s important to understand which is cheapest, has the smallest environmental impact, and enables secure supply chains,” Darling said. ​”For many other materials, water is underexplored as a source, and that’s something we’re paying increasingly more attention to.” The technologies that Darling and his colleagues are exploring to extract critical materials from different types of water range from the traditional (like membranes) to the innovative (like interfacial solar steam generators). Omar Kazi, a Ph.D. student in molecular engineering at the University of Chicago working with Darling, is studying methods to concentrate wastewater streams to recover valuable materials. ​”Getting rid of the water through evaporation is an energy-intensive and slow process,” Kazi said. ​”In geothermal brines, it can take years for water to evaporate to be able to recover the lithium that’s contained in them, which creates a huge bottleneck. The question we are asking is ​’how we can make the water evaporate faster?'” One way to do that could be through the use of porous photothermal materials, which convert light to heat efficiently. These light absorbers act like a black T-shirt that heats up on a sunny day. That heat is transferred to the water directly at the interface with the surrounding air, significantly accelerating evaporation. Overall, Darling noted, Argonne has rich capabilities in supply chain, life cycle and technoeconomic analyses. In addition, the laboratory specializes in the materials, chemistry and process engineering relevant to critical material extraction. This uniquely positions the lab to help achieve a more secure and circular economy of materials, especially when it comes to getting more out of water streams. A paper based on the study, ​”Material design strategies for recovery of critical resources from water,” appeared online in Advanced Materials on March 31. In addition to Darling and Kazi, other authors of the study include Argonne’s Wen Chen, Jamila Eatman, Feng Gao, Yining Liu, Yuqin Wang, and Zijing Xia. This work was supported as part of the Advanced Materials for Energy-Water Systems (AMEWS) Center, an Energy Frontier Research Center funded by the U.S. Department of Energy, Office of Science, Basic Energy Sciences at Argonne National Laboratory.