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Bonne nouvelle pour les amoureux de rétro-gaming et de matériel haut de gamme ! La société 8BitDo vient d’annoncer la sortie de nouvelles versions de son clavier mécanique rétro, désormais adaptées aux layouts européens. Les configurations QWERTZ, AZERTY, ES et NORD font leur entrée. Alors que le modèle britannique adopte un design inspiré du Commodore 64. Un hommage au rétro Lancé en 2023, le clavier mécanique rétro d’8BitDo fusionne un design old-school inspiré des années 80 avec des technologies du [...]
L’article 8BitDo, enfin des claviers avec du QWERTZ et de l’AZERTY est apparu en premier sur JVMag.
“What makes a good astronaut?” asks director Hannah Berryman in the opening scene of Spacewoman. It’s a question few can answer better than Eileen Collins. As the first woman to pilot and command a NASA Space Shuttle, her career was marked by historic milestones, extraordinary challenges and personal sacrifices. Collins looks down the lens of the camera and, as she pauses for thought, we cut to footage of her being suited up in astronaut gear for the third time. “I would say…a person who is not prone to panicking.”
In Spacewoman, Berryman crafts a thoughtful, emotionally resonant documentary that traces Collins’s life from a determined young girl in Elmira, New York, to a spaceflight pioneer.
The film’s strength lies in its compelling balance of personal narrative and technical achievement. Through intimate interviews with Collins, her family and former colleagues, alongside a wealth of archival footage, Spacewoman paints a vivid portrait of a woman whose journey was anything but straightforward. From growing up in a working-class family affected by her parents’ divorce and Hurricane Agnes’s destruction, to excelling in the male-dominated world of aviation and space exploration, Collins’s resilience shines through.
Berryman wisely centres the film on the four key missions that defined Collins’s time at NASA. While this approach necessitates a brisk overview of her early military career, it allows for an in-depth exploration of the stakes, risks and triumphs of spaceflight. Collins’s pioneering 1995 mission, STS-63, saw her pilot the Space Shuttle Discovery in the first rendezvous with the Russian space station Mir, a mission fraught with political and technical challenges. The archival footage from this and subsequent missions provides gripping, edge-of-your-seat moments that demonstrate both the precision and unpredictability of space travel.
Perhaps Spacewoman’s most affecting thread is its examination of how Collins’s career intersected with her family life. Her daughter, Bridget, born shortly after her first mission, offers a poignant perspective on growing up with a mother whose job carried life-threatening risks. In one of the film’s most emotionally charged scenes, Collins recounts explaining the Challenger disaster to a young Bridget. Despite her mother’s assurances that NASA had learned from the tragedy, the subsequent Columbia disaster two weeks later underscores the constant shadow of danger inherent in space exploration.
These deeply personal reflections elevate Spacewoman beyond a straightforward biographical documentary. Collins’s son Luke, though younger and less directly affected by his mother’s missions, also shares touching memories, offering a fuller picture of a family shaped by space exploration’s highs and lows. Berryman’s thoughtful editing intertwines these recollections with historic footage, making the stakes feel immediate and profoundly human.
The film’s tension peaks during Collins’s final mission, STS-114, the first “return to flight” after Columbia. As the mission teeters on the brink of disaster due to familiar technical issues, Berryman builds a heart-pounding narrative, even for viewers unfamiliar with the complexities of spaceflight. Without getting bogged down in technical jargon, she captures the intense pressure of a mission fraught with tension – for those on Earth, at least.
Berryman’s previous films include Miss World 1970: Beauty Queens and Bedlam and Banned, the Mary Whitehouse Story. In a recent episode of the Physics World Stories podcast, she told me that she was inspired to make the film after reading Collins’s autobiography Through the Glass Ceiling to the Stars. “It was so personal,” she said, “it took me into space and I thought maybe we could do that with the viewer.” Collins herself joined us for that podcast episode and I found her to be that same calm, centred, thoughtful person we see in the film and who NASA clearly very carefully chose to command such an important mission.
Spacewoman isn’t just about near-misses and peril. It also celebrates moments of wonder: Collins describing her first sunrise from space or recalling the chocolate shuttles she brought as gifts for the Mir cosmonauts. These light-hearted anecdotes reveal her deep appreciation for the unique experience of being an astronaut. On the podcast, I asked Collins what one lesson she would bring from space to life on Earth. After her customary moment’s pause for thought, she replied “Reading books about science fiction is very important.” She was a fan of science fiction in her younger years , which enabled her to dream of the future that she realized at NASA and in space. But, she told me, these days she also reads about real science of the future (she was deep into a book on artificial intelligence when we spoke) and history too. Looking back at Collins’s history in space certainly holds lessons for us all.
Berryman’s directorial focus ultimately circles back to a profound question: how much risk is acceptable in the pursuit of human progress? Spacewoman suggests that those committed to something greater than themselves are willing to risk everything. Collins’s career embodies this ethos, defined by an unshakeable resolve, even in the face of overwhelming odds.
In the film’s closing moments, we see Collins speaking to a wide-eyed girl at a book signing. The voiceover from interviews talks of the women slated to be instrumental in humanity’s return to the Moon and future missions to Mars. If there’s one thing I would change about the film, it’s that the final word is given to someone other than Collins. The message is a fitting summation of her life and legacy, but I would like to have seen it delivered with her understated confidence of someone who has lived it. It’s a quibble though in a compelling film that I would recommend to anyone with an interest in space travel or the human experience here on Earth.
When someone as accomplished as Collins says that you need to work hard and practise, practise, practise it has a gravitas few others can muster. After all, she spent 10 years practising to fly the Space Shuttle – and got to do it for real twice. We see Collins speak directly to the wide-eyed girl in a flight suit as she signs her book and, as she does so, you can feel the words really hit home precisely because of who says them: “Reach for the stars. Don’t give up. Keep trying because you can do it.”
Spacewoman is more than a tribute to a trailblazer; it’s a testament to human perseverance, curiosity and courage. In Collins’s story, Berryman finds a gripping, deeply personal narrative that will resonate with audiences across the planet.
The post <em>Spacewoman</em>: trailblazing astronaut Eileen Collins makes for a compelling and thoughtful documentary subject appeared first on Physics World.
Watch this short video filmed at the APS March Meeting in 2024, where Mark Elo, chief marketing officer of Tabor Quantum Solutions, introduces the Echo-5Q, which he explains is an industry collaboration between FormFactor and Tabor Quantum Systems, using the QuantWare quantum processing unit (QPU).
Elo points out that it is an out-of-the-box solution, allowing customers to order a full-stack system, including the software, refrigeration, control electronics and the actual QPU. With the Echo-5, it gets delivered and installed, so that the customer can start doing quantum measurements immediately. He explains that the Echo-5Q is designed at a price and feature point that increases the accessibility for on-site quantum computing.
Brandon Boiko, senior applications engineer with FormFactor, describes the how FormFactor developed the dilution refrigeration technology that the qubits get installed into. Boiko explains that the product has been designed to reduce the cost of entry into the quantum field – made accessible through FormFactor’s test-and- measurement programme, which allows people to bring their samples on site to take measurements.
Alessandro Bruno is founder and CEO of QuantWare, which provides the quantum processor for the Echo-5Q, the part that sits at the milli Kelvin stage of the dilution refrigerator, and that hosts five qubits. Bruno hopes that the Echo-5Q will democratize access to quantum devices – for education, academic research and start-ups.
The post Introducing the Echo-5Q: a collaboration between FormFactor, Tabor Quantum Systems and QuantWare appeared first on Physics World.
Researchers at the University of Chicago’s Pritzker School of Molecular Engineering have created a groundbreaking hydrogel that doubles as a semiconductor. The material combines the soft, flexible properties of biological tissues with the electronic capabilities of semiconductors, making it ideal for advanced medical devices.
In a study published in Science, the research team, led by Sihong Wang, developed a stretchy, jelly-like material that provides the robust semiconducting properties necessary for use in devices such as pacemakers, biosensors and drug delivery systems.
Hydrogels are ideal for many biomedical applications because they are soft, flexible and water-absorbent – just like human tissues. Material scientists, long recognizing the vast potential of hydrogels, have pushed the boundaries of this class of material. One way is to create hydrogels with semiconducting abilities that can be useful for transmitting information between living tissues and bioelectronic device interfaces – in other words, a hydrogel semiconductor.
Imparting semiconducting properties to hydrogels is no easy task, however. Semiconductors, while known for their remarkable electronic properties, are typically rigid, brittle and water-repellent, making them inherently incompatible with hydrogels. By overcoming this fundamental mismatch, Wang and his team have created a material that could revolutionize the way medical devices interface with the human body.
Traditional hydrogels are made by dissolving hydrogel precursors (monomers or polymers) in water and adding chemicals to crosslink the polymers and form a water-swelled state. Since most polymers are inherently insulating, creating a hydrogel with semiconducting properties requires a special class of semiconducting polymers. The challenges do not stop there, however. These polymers typically only dissolve in organic solvents, not in water.
“The question becomes how to achieve a well-dispersed distribution of these semiconducting materials within a hydrogel matrix,” says first author Yahao Dai, a PhD student in the Wang lab. “This isn’t just about randomly dispersing particles into the matrix. To achieve strong electrical performance, a 3D interconnected network is essential for effective charge transport. So, the fundamental question is: how do you build a hydrophobic, 3D interconnected network within the hydrogel matrix?”
To address this challenge, the researchers first dissolved the polymer in an organic solvent that is miscible with water, forming an organogel – a gel-like material composed of an organic liquid phase in a 3D gel network. They then immersed the organogel in water and allowed the water to gradually replace the organic solvent, transforming it into a hydrogel.
The researchers point out that this versatile solvent exchange process can be adapted to a variety of semiconducting polymers, opening up new possibilities for hydrogel semiconductors with diverse applications.
The result is a hydrogel semiconductor material that’s soft enough to match the feel of human tissue. With a Young’s modulus as low as 81 kPa – comparable to that of jelly – and the ability to stretch up to 150% of its original length, this material mimics the flexibility and softness of living tissue. These tissue-like characteristics allow the material to seamlessly interface with the human body, reducing the inflammation and immune responses that are often triggered by rigid medical implants.
The material also has a high charge carrier mobility, a measure of its ability to efficiently transmit electrical signals, of up to 1.4 cm2/V/s. This makes it suitable for biomedical devices that require effective semiconducting performance.
The potential applications extend beyond implanted devices. The material’s high hydration and porosity enable efficient volumetric biosensing and mass transport throughout the entire thickness of the semiconducting layer, which is useful for biosensing, tissue engineering and drug delivery applications. The hydrogel also responds to light effectively, opening up possibilities for light-controlled therapies, such as light-activated wireless pacemakers or wound dressings that use heat to accelerate healing.
The research team’s hydrogel material is now patented and being commercialized through UChicago’s Polsky Center for Entrepreneurship and Innovation. “Our goal is to further develop this material system and enhance its performance and application space,” says Dai. While the immediate focus is on enhancing the electrical and light modulation properties of the hydrogel, the team envisions future work in biochemical sensing.
“An important consideration is how to functionalize various bioreceptors within the hydrogel semiconductor,” explains Dai. “As each biomarker requires a specific bioreceptor, the goal is to target as many biomarkers as possible.”
The team is already exploring new methods to incorporate bioreceptors, such as antibodies and aptamers, within the hydrogels. With these advances, this class of semiconductor hydrogels could act as next-generation interfaces between human tissues and bioelectronic devices, from sensors to tailored drug-delivery systems. This breakthrough material may soon bridge the gap between living systems and electronics in ways once thought impossible.
The post Tissue-like hydrogel semiconductors show promise for next-generation bioelectronics appeared first on Physics World.
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