Posted in futurism
This Video Explains Hydrolysis of ATP
Thank You For Watching.
Please Like And Subscribe to Our Channel: https://www.youtube.com/EasyPeasyLearning.
Like Our Facebook Page: https://www.facebook.com/learningeasypeasy/
Join Our Facebook Group: https://www.facebook.com/groups/460057834950033
Support Our Channel: https://www.patreon.com/supereasypeasy.
Link of Adenosine Triphosphate ATP Video : https://youtu.be/SHSv789fyno
Collective dynamics are ubiquitous in the natural world. From neural circuits to animal groups, there are countless instances in which the interactions among large numbers of elementary units bestow surprisingly complex patterns of tantalizing beauty on the collective. One of the longstanding goals of researchers in many fields is to understand behaviors of a large group of individual units by monitoring the actions of a single unit. For example, an ornithologist can learn many things about the behaviors of a flock by monitoring only a single bird.
Of greater difficulty is understanding the size of a collection of units by observing a single unit. No matter how many birds one tags with monitoring equipment, one can never be assured of having tagged the entire flock. Yet, while the ability to calculate the size of a collective from individual behaviors would be a key tool for any field, there are only a handful of recent papers trying to tackle the seemingly unsolvable problem.
In a newly published study appearing in Communications Physics, investigators led by Maurizio Porfiri, Institute Professor of Mechanical and Aerospace Engineering and Biomedical Engineering, and a member of the Center for Urban Science and Progress (CUSP) at the NYU Tandon School of Engineering; and Pietro De Lellis of the University of Naples, Italy, offer a paradigm to solve this problem, one that builds upon precepts that can be traced back to the work of Einstein.
It’s a very good plan for some very good boys and girls.
The U.S. Army’s military working dogs are entering augmented reality, thanks to the service’s investment in a company developing AR goggles for canines.
➡ You love badass military tech. So do we. Let’s nerd out together.
Researchers used radiative cooling to generate enough to power LEDs or charge a cell phone.
NASA has agreed to test startup SpinLaunch’s kinetic launcher, a giant circular accelerator that aims to shoot 200 kilogram satellites into space.
The California-based SpinLaunch’s launcher is located at the Spaceport America facility in New Mexico where it will carry out a test flight with NASA later this year, according to the firm.
SpinLaunch says it will launch a NASA payload later this year after signing an agreement with the space agency.
A new technique for synthesising and screening molecules developed by Danish researchers has been described in a paper published in Nature Chemistry.
The technique, dubbed “single particle combinatorial lipidic nanocontainer fusion based on DNA-mediated fusion” or SPARCLD, uses tiny soap-like “bubbles” to produce more than 40,000 different molecules on an area the size of a pinhead.
The bubbles form “nano-containers” inside which molecules can be produced using DNA nanotechnology. About 42,000 nano-containers can fit on one square millimetre.
Posted in futurism
Ready for what’s next? Watch our Unreal Engine 5 sizzle reel for a glimpse at what’s now possible with real-time technology.
With Unreal Engine 5, we aim to empower both large and small teams to really push the boundaries of creativity, visually and interactively. UE5 will enable game developers and creators across industries to realize next-generation real-time 3D content and experiences with greater freedom, fidelity, and flexibility than ever before.
A new study from Washington State University shows that honey might be the key to the future of neuromorphic computing, and thus, computing as a whole.
The Lunar Crater Radio Telescope is now moving into Phase 2 of development. It’ll be built by robots, into a natural bowl-shaped crater on the moon’s far side. If completed, it’ll be the largest radio telescope in the solar system.
Our planet supports approximately 8.7 million species, of which over a quarter live in water.
But humans can have a hard time comprehending numbers this big, so it can be difficult to really appreciate the breadth of this incredible diversity of life on Earth.
In order to fully grasp this scale, we draw from research by Bar-On et al. to break down the total composition of the living world, in terms of its biomass, and where we fit into this picture.
