Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog

Category: sustainability

ARK Robotics Research

Automation and robotics, particularly with the integration of AI, are transforming industries and poised to significantly impact the workforce, but are likely to lead to a reduction in work hours and increased productivity rather than total job destruction.

## Questions to inspire discussion.

Investment & Market Opportunity.

đŸ€– Q: What is the revenue potential for robotics by 2025? A: ARK Invest projects a $26 trillion global revenue opportunity across household and manufacturing robotics by 2025, driven by convergence of humanoid robots, AI, and computer vision technologies.

💰 Q: How should companies evaluate robot ROI for deployment? A: Robots are worth paying for based on task-specific capabilities delivering 2–10% productivity gains, unlike autonomous vehicles requiring full job performance—Roomba succeeded despite early limitations by being novel and time-saving for specific tasks.

Implementation Strategy.

Continue reading “ARK Robotics Research” | >

Magnetic control of lithium enables a safe, explosion-free ‘dream battery’

A new battery technology has been developed that delivers significantly higher energy storage—enough to alleviate EV range concerns—while lowering the risk of thermal runaway and explosion.

A research team at POSTECH has developed a next-generation hybrid anode that uses an external magnetic field to regulate lithium-ion transport, effectively suppressing dendrite growth in high-energy-density electrodes.

A POSTECH research team—led by Professor Won Bae Kim of the Department of Chemical Engineering and the Graduate School of Battery Engineering, together with Dr. Song Kyu Kang and integrated Ph.D. student Minho Kim—has introduced a “magneto-conversion” strategy that applies an external magnetic field to ferromagnetic manganese ferrite conversion-type anodes.

Safe and affordable fast-charging batteries: Multi-layered alkali metal structures open the door to energy of the future

Skoltech scientists conducted a study that advances research on future batteries. Their paper, published in Small, sheds light on recent advances in designing multilayered structures of alkali metals, such as lithium, sodium, and potassium, within carbon anode materials.

This technology has the potential to transform the energy storage market, enabling electric vehicles to charge in minutes and providing green energy with stable, safe, and affordable storage systems.

How multilayered structures improve batteries For years, ions were believed to form only single-atom layers in a battery’s carbon materials, such as graphite. In 2018, researchers used a high-precision electron microscope and discovered a new configuration with ultradense, multiatom layers of lithium forming between two sheets of graphene.

Dan Ives On Why 2026 Is The Start Of Tesla’s $3 Trillion AI Chapter

Tesla is poised to reach a $3 trillion valuation by 2026, driven by its advancements in AI, autonomous vehicles, and robotics, which are expected to outweigh its challenges in EV sales and regulatory pressures ## Questions to inspire discussion.

Autonomous Driving Deployment Timeline.

🚕 Q: What are Tesla’s specific robotaxi deployment targets for 2026?

A: Tesla aims to launch robotaxis without safety drivers in 30 cities by 2026 while significantly expanding geo-fenced areas in cities like Austin, leveraging its 10 million cars on the road to scale autonomy faster than competitors through superior data collection advantage.

🎯 Q: What evidence do investors need to see in 2026 to validate Tesla’s autonomous strategy?

A: Investors must see city-by-city proof of autonomous accuracy, achievement of true level 5 autonomy, measurable regulatory progress, and rapid scaling capability across multiple markets to confirm the long-term bullish thesis.

Continue reading “Dan Ives On Why 2026 Is The Start Of Tesla’s Trillion AI Chapter” | >

How sustainability is driving innovation in functionalized graphene materials

Graphene is often described as a wonder material. It is strong, electrically conductive, thermally efficient, and remarkably versatile. Yet despite more than a decade of excitement, many graphene-based technologies still struggle to move beyond the laboratory.

One of the key challenges is that graphene does not readily dissolve in common solvents, forcing researchers to rely on harsh, multi-step functionalization/modification processes to make it usable.

As a researcher working at the intersection of green chemistry and nanomaterials, I have often found myself asking a simple question: Can we design advanced materials without relying on environmentally costly processes?

Redesigned carbon molecules boost battery safety, durability and power

Research published in the Journal of the American Chemical Society demonstrates a new way to make carbon-based battery materials much safer, longer lasting, and more powerful by fundamentally redesigning how fullerene molecules are connected.

Today’s lithium-ion batteries rely mainly on graphite, which limits fast-charging speed and poses safety risks due to lithium plating. These research findings mean progress toward safer electric vehicles, longer-lasting consumer electronics, and more reliable renewable-energy storage.

Why Everyone Is Talking About Data Centers In Space

Questions to inspire discussion.

Launch Economics & Viability.

🚀 Q: What launch cost makes space data centers economically competitive? A: Space data centers become cost-competitive with ground systems when launch costs drop to approximately $200/kg, according to Google’s Suncatcher paper, making the economics viable for moving compute infrastructure off-Earth.

💰 Q: Why might SpaceX pursue a $1.5 trillion IPO valuation? A: The projected $1.5 trillion SpaceX IPO valuation is speculated to fund the capital-intensive race to establish space-based data centers and secure the best orbital positions before competitors.

🏱 Q: Which companies can realistically build space data centers first? A: Vertically integrated organizations like SpaceX, Relativity Space, and Blue Origin lead because they control launch infrastructure, can self-fund deployment, and serve as their own customers for space compute capacity.

đŸ›°ïž Q: How would space data centers physically connect GPUs across satellites? A: Multiple free-flying satellites in formation (like 20+ Starlink satellites) use inter-satellite optical connections to enable communication between GPUs, creating high-density computing clusters in orbit.

Continue reading “Why Everyone Is Talking About Data Centers In Space” | >

Analyzing Bill Ackman’s SpaceX IPO Offer w/ Tesla Larry

đŸ”č Q: What specific cost advantages does SPARC offer beyond eliminating underwriting fees? A: SPARC reduces friction, cost, and time by bypassing the traditional investment banking process entirely, eliminating promotional fees and creating a cleaner, more transparent process than traditional SPACs.

đŸ”č Q: How would Tesla shareholders get early access to SpaceX shares through SPARC? A: Tesla shareholders would receive special rights to acquire SpaceX shares at the IPO price before the public, potentially through warrants at a discounted price, allowing them to benefit from SpaceX’s future growth.

đŸ”č Q: What advantage does SPARC provide Tesla investors over traditional IPO allocation? A: SPARC enables more equitable allocation of SpaceX shares to Tesla investors, avoiding the traditional gated process that benefits Wall Street bankers’ friends and their preferred clients.

đŸ”č Q: How could SpaceX share access impact Tesla’s stock price? A: The SPARC structure allowing Tesla shareholders to receive warrants for SpaceX shares at discounted prices could potentially boost Tesla’s stock price by providing unique value to existing shareholders.

Pricing Control.

đŸ”č Q: Who controls pricing in SPARC versus traditional IPO? A: SPARC allows the public to set the price rather than banker control, giving SpaceX more control over pricing decisions compared to traditional IPO where investment banks determine valuation.

Continue reading “Analyzing Bill Ackman’s SpaceX IPO Offer w/ Tesla Larry” | >

Production of hydrogen and carbon nanotubes from methane using a multi-pass floating catalyst chemical vapour deposition reactor with process gas recycling

Methane pyrolysis produces hydrogen and carbon materials, but some approaches based on chemical vapour deposition actually consume hydrogen to mitigate unwanted side reactions. Here Peden et al. use gas recycling in a multi-pass floating catalyst chemical vapour deposition reactor to produce hydrogen alongside carbon nanotube aerogels.

/* */