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In a paper for Nature this month, researchers claim the development of mega-constellations like Starlink “risks multiple tragedies of the commons, including tragedies to ground-based astronomy, Earth orbit, and Earth’s upper atmosphere.”


Perhaps the biggest effects could come as the satellites start to deorbit, sparking what could be a major experiment in geoengineering.

This week’s SpaceX launch is the 29th batch of Starlink satellites since the first in May 2019, building out the firm’s internet connectivity constellation. Starlink aims to offer high-speed and low latency internet access almost anywhere with a view of a ground terminal.

SpaceX has now launched 1737 satellites for Starlink, with 951 operational. Starlink satellites typically take a few months to move into position and start operations. Starlink is already the biggest single constellation in space, but the firm has applied for permission to launch up to 42000 satellites.

First-of-its-kind study shows how engineered immune cells move faster to attack the tumor.

A groundbreaking study led by engineering and medical researchers at the University of Minnesota Twin Cities shows how engineered immune cells used in new cancer therapies can overcome physical barriers to allow a patient’s own immune system to fight tumors. The research could improve cancer therapies in the future for millions of people worldwide.

The research is published in Nature Communications, a peer-reviewed, open access, scientific journal published by Nature Research.

As the need for urgent climate solutions grows, scientists want to put more research into a technology known as solar geoengineering — the idea of chemically altering the atmosphere to reflect sunlight away from Earth.

It is seen as a potential method of cooling the planet and offsetting climate change. But could such a technology curtail a climate catastrophe — or become the cause of it?

Those against solar geoengineering fear unintended consequences, including irreversible changes to weather patterns, and many climate activists are wary of using the Earth’s atmosphere as a testing ground. Last month in Sweden, an experiment led by Harvard University researchers was cancelled following opposition by environmental and indigenous groups. Researchers had planned on testing a high-altitude balloon that could be used to disperse reflective aerosol particles into the atmosphere.

In this episode of The Stream, we’ll learn more about solar geoengineering and the debate surrounding it.

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When one of the largest modern earthquakes struck Japan on March 11, 2011, the nuclear reactors at Fukushima-Daiichi automatically shut down, as designed. The emergency systems, which would have helped maintain the necessary cooling of the core, were destroyed by the subsequent tsunami. Because the reactor could no longer cool itself, the core overheated, resulting in a severe nuclear meltdown, the likes of which haven’t been seen since the Chernobyl disaster in 1986.

Since then, reactors have improved exponentially in terms of safety, sustainability and efficiency. Unlike the light-water reactors at Fukushima, which had liquid coolant and , the current generation of reactors has a variety of coolant options, including molten-salt mixtures, supercritical water and even gases like helium.

Dr. Jean Ragusa and Dr. Mauricio Eduardo Tano Retamales from the Department of Nuclear Engineering at Texas A&M University have been studying a new fourth-generation , -bed reactors. Pebble-bed reactors use spherical fuel elements (known as pebbles) and a fluid coolant (usually a gas).

“Never, never ask me for a shortcut.” her mom said while she was growing up.

MiMi Aung (born 1968) is a Burmese 🇲🇲 American engineer and project manager at Jet Propulsion Laboratory (JPL).

She is the lead engineer on the Mars Helicopter Ingenuity, the first extraterrestrial aircraft which landed on Mars today.

She was inspired by her mother to study science, maths and engineering. Her mother was the first woman in Myanmar to get a PhD in mathematics.

She tested the technology she and her colleagues developed for seven years at NASA.

Mars’ atmosphere is a lot thinner than Earth’s. This means to keep the helicopter in the air, the blades must spin very fast and it can’t weigh more than 2 kilograms.

Ingenuity’s mission on Mars is to help Perseverance find the best routes around Mars.

“The most important thing is to understand the fundamentals and know what your goals and strengths are. Then work hard on it. You have to know that like my mother said, there are no shortcuts for success,” she said.

The last photo? She wrote a speech in case the mission fails. She tore it.

Congratulations.

#nasa #engineering #space #ingenuity.

Credit: all images’ owners.

Circa 2020


Learn how a young team of additive manufacturing engineers helped bring 3D printed parts to the design of the GE9X, the world’s largest jet engine.

Stefka Petkova enjoys building things. It’s a passion she’s had since she was a small child when her dad, an electrician who liked to work on cars, kept the door to his workshop open. “I was exposed to that as a very young child and just got a lot of encouragement,” says Petkova, who she spent many afternoons watching him weld and wire automobiles.

Her childhood tinkering led her to study mechanical engineering at the University of North Florida, near America’s Space Coast, where she joined the school’s space club. She traveled with the club to Cocoa Beach to watch the liftoff of Space Shuttle Atlantis in 2011, NASA’s final flight in its Space Shuttle Program. “At the Atlantis launch, we were able to go in the overhaul facility, touch the space tiles protecting the shuttles and talk to the engineers,” she says. “It was an amazing experience.”

Israel’s Aquarius Engines this week gave the world a first look at the tiny hydrogen engine it hopes can supplant gas engine-generators and hydrogen fuel cells in future electrified vehicles. Weighing just 22 lb (10 kg), the simple engine uses a single moving piston to develop power. Beyond vehicles, Aquarius is developing the engine for use as an off-grid micro-generator.

First created in 2014, Aquarius’ efficient single-piston linear engine has a single central cylinder in which the piston moves between two engine heads. In previous iterations, Aquarius used more conventional fossil fuels to create combustion, but now it’s turning attention to emissions-slashing hydrogen. The company says Austrian engineering firm AVL-Schrick recently completed third-party testing, verifying that a modified version of the engine can operate purely on hydrogen.

“It was always our dream at Aquarius Engines to breathe oxygen into hydrogen technology as the fuel of the future,” explains Aquarius chairman Gal Fridman. “From initial tests, it appears that our hydrogen engine, that doesn’t require costly hydrogen fuel-cells, could be the affordable, green and sustainable answer to the challenges faced by global transport and remote energy production.”

www.iBiology.org.

Dr. Kate Adamala describes what synthetic cells are and how they can teach us the fundamental principles of life.

Life on Earth evolved once — this means that all biological systems on our planet are rooted in the same fundamental framework. This framework is extremely complex and we have yet to fully understand the processes inside each living cell. One way of understanding complex systems is to break them down into simpler parts. This is the principle of engineering the synthetic cell: to use our current knowledge of biology for building a living cell with the least amount of parts and complexity. Synthetic cells can be used to teach us about the basic principles of life and evolution, and they hold promise for a range of applications including biomaterials and drug development. Dr. Kate Adamala narrates an introduction to this exciting field.

0:00 Introduction.
2:22 How do we build a synthetic cell?
7:12 How can we use synthetic cells?

Speaker Biography:
Dr. Kate Adamala is a synthetic biologist and a McKnight Land-Grant Assistant Professor in the Department of Genetics, Cell Biology and Development at the University of Minnesota. Her research interests include astrobiology, synthetic cell engineering and biocomputing. Adamala is a co-founder and steering group member of the international Build-a-Cell Initiative, which seeks to broaden the impact of synthetic cell engineering. Find more information on Adamala’s lab at:
http://www.protobiology.org.

Credits:
Brittany Anderton (iBiology): Producer.
Eric Kornblum (iBiology): Videographer and Editor.
Kate Adamala (UMN): Graphics and Narration.

A University of California San Diego engineering professor has solved one of the biggest mysteries in geophysics: What causes deep-focus earthquakes?

These mysterious earthquakes originate between 400 and 700 kilometers below the surface of the Earth and have been recorded with magnitudes up to 8.3 on the Richter scale.

Xanthippi Markenscoff, a distinguished professor in the Department of Mechanical and Aerospace Engineering at the UC San Diego Jacobs School of Engineering, is the person who solved this mystery. Her paper “Volume collapse instabilities in deep earthquakes: a shear source nucleated and driven by pressure” appears in the Journal of the Mechanics and Physics of Solids.

As researchers learn more about the brain, it has become clear that responsive neurostimulation is becoming increasingly effective at probing neural circuit function and treating neuropsychiatric disorders, such as epilepsy and Parkinson’s disease. But current approaches to designing a fully implantable and biocompatible device able to make such interventions have major limitations: their resolution isn’t high enough and most require large, bulky components that make implantation difficult with risk of complications.

A Columbia Engineering team led by Dion Khodagholy, assistant professor of electrical engineering, has come up with a new approach that shows great promise to improve such devices. Building on their earlier work to develop smaller, more efficient conformable bioelectronic transistors and materials, the researchers orchestrated their devices to create implantable circuits that enable allow reading and manipulation of brain circuits. Their multiplex-then-amplify (MTA) system requires only one amplifier per multiplexer, in contrast to that need an equal number of amplifiers as number of channels.

“It is critical to be able to detect and intervene to treat brain-disorder-related symptoms, such as epileptic seizures, in real time,” said Khodagholy, a leader in bio-and neuroelectronics design. “Not only is our system much smaller and more flexible than current devices, but it also enables simultaneous stimulation of arbitrary waveforms on multiple independent channels, so it is much more versatile.