Violence is language that needs no translation. Everyone across the world, every culture, every country, every social group - from elites to homeless can converse in it using the same vocabulary.

It is useful to have some degree of mastery in this discipline. Sometimes it is the only language that can deliver the important message to an unwilling listener.

The paper is very light on details and doesn't offer any evidence of the stated hypothesis beyond referencing other work.

You absolutely need to solve the gatekeeping and reputation part, otherwise your newly-minted open access journal would be filled to the brim with cranks and charlatans.

also dark materialists and dark energetists

Very tough engineering problem. Amount transported is 92 atoms. A mole (1 gram) of anti-hydrogen is 6.23x10^23 atoms.

When I visited CERN, they mentioned that there were some large number of protons in the ring at a time, and the runs would last a significant amount of wall clock time. (Don’t remember the exact numbers, but I think it was like 10^19 atoms of H, and days of wall clock)

The upshot was, it was likely that less than a mol of hydrogen had been run through the ring.

Interstellar flight is a new physics problem, not a smash-the-tiny-rocks-together-to-make-bigger-bang problem.

We're not going anywhere without a revolution in our understanding of the universe.

My memory is that 1g of constant acceleration grants sufficient relativity to make it to the edge of the known universe in a current human lifespan.

Now, it's true, there's some slight issues such as radiation, food storage/production, psychological effects, and any random space rocks obliterating your craft, all of which could reasonably turn out to be enough to make it not work. We also don't have a fuel source that can provide 1g of constant acceleration for 80 years for a reasonably sized space ship, though again my memory is that nothing prohibits it from a physics perspective (this is where my knowledge/understanding get prohibitively poor. I'm not sure how the math works if you stick a thousand ion drives to a spaceship that's already in space or if you just need a huge snifter of compressed hydrogen or if you can just use nuclear propulsion but I'm pretty sure that antimatter would do it, if you could bring yourself to waste the money. But maybe we don't have a plausible way to contain it so what do I know).

Maybe I'm remembering wrong, or maybe I glossed over what's currently considered a physics, rather than engineering/economic/materials science problem, but that's what it looked like last I checked.

Alpha Centauri yes, the edge of the universe no :D

Edge of observable universe is something like 46 billion light-years away, even at 0.9c thats 50 billion years of travel (22 billion years experienced by the traveller)

But yes, you can travel places by constant acceleration but unfortunately it still dwarfs in comparison to those places out of our reach.

Unfortunately also, the universe is expanding at a rate faster than the speed of light so you actually cant ever reach the edge

If the craft could maintain a constant 1G acceleration the entire time or more it is feasible to get near the known edge for the traveler, assuming we could make and utilize enough anti-matter to do it and that what we see as the edge here is actually a recognizable edge once you are out there.

0.9C would be reached in only a year and a half for the traveler under constant 1G acceleration. After 2.5 years you would be at .99c, and at a bit over 3.5 years you would hit .999c with a 6x time dilation compared to earth. After 6 years of acceleration it would be .99999c and Earth would be 200 years in the past. As you approach 12 years you would be going 0.9999999999c and Earth would have experienced almost 70,000 years. As you go past 16 years you would be in the millions of years and as you got past 20 years you would be in the billions of years.

Of course doing that may only be feasible with anti-matter energy storage. The next best energy source is fusion energy but it is 2 orders of magnitude less dense. Perhaps some kind of ram scoop would make that route possible but that is going beyond just speculation because we don't know if you can feasibly capture random particles at that speed even assuming you didn't explode from just hitting them in the first place.

You don't need new physics for interstellar spaceflight - 16 km/s of dV is enough. you don't even need to go that much faster to slowly spread among the stars. There are a lot of smaller bodies all the way from Sun to Alpha Centauri. As long as you hop between them within reasonable time in a few thousand years you can become a true interstellar civilization, while going at much-slower-than-light velocity (similar to Polynesian colonization of Pacific).

Not with that attitude, we're not!

> antimatter drive is the logical next step in propulsion after fusion

Maybe. Beamed propulsion makes a hell of a lot more sense in the solar system.

Interesting application too (satellite imagery agent for NVDI index).

TL;DR: it is new semiconductor fabs that Elon wants to build.

M5 are 9-18 cores and optimized for power-efficiency, those are more like Xeons, with 200-300W TDP, I'd bet.

If M5 has 9-18 cores and takes ~20w, then that's ~1-2w per CPU core. If these are 200-300W, and have ~100-200 CPU cores, then guess what? That's also ~1-2w per CPU core.

Xeons, Epycs, whatever this is - they are all also typically optimized for power efficiency. That's how they can fit so many CPU cores in 200-300W.

It is a 88-core ARM v9 chip, for somewhat more detailed spec.

Vera does what NVIDIA calls Spatial Multithreading, "physically partitioning each core’s resources rather than time slicing them, allowing the system to optimize for performance or density at runtime." A kind of static hyperthreading; you get two threads per core.

It's somewhat different from how x86 chips do simultaneous multithreading (SMT),

Seems like curious terminology from NV. In estabilished use, SMT means executing instructions from several cpu threads concurrently in the OOO CPU's execution units so they are not starved from work, whereas timeslicing conventionally means context switching between threads/processes, alternating temporally.

In operating systems timeslicing means giving a quantum of execution time to each process, and context switching between processes. Not normally a term used in computer architecture but possibly the characterisation would fit a barrer processor rather than SMT.

Hmm, the 128-core Ampere Altra CPU is already available, and in a case from System76. I wonder what else differentiates it.

If they're going to build CPUs I wish they had used Risc-V instead. They are using it somewhat already.

You can see here[1] what the specs are for the CPU (listed as "NVIDIA Vera Rubin Superchip").

The CPU is integrated with two Rubin GPUs but each of the CPU cores has dedicated FP8 acceleration as well.

1. https://www.nvidia.com/en-us/data-center/vera-rubin-nvl72/

I own one of these systems. My interpretation is the Ampere systems are targeted at lower cost scale out. The Ampere Altra CPUs are limited to DDR4. The raw single core performance doesn’t match Intel or AMD offerings. You get a lot of cores for a lower hardware cost and at lower energy usage.

The Nvidia CPUs are designed for a very specific use case. They are designed for high performance with less concern about cost control.

The newer AmpereOne CPUs use DDR5 with the AmpereOne M supporting even higher memory bandwidth. Even then, I doubt the AmpereOne CPUs will match the performance of the Nvidia Rubin CPUs. But the Ampere processors are available for general use. I am guessing that Nvidia is only going to sell the complete rack system and only to high-volume customers.

In terms of military technology we now have aerial and naval drones clearly outperforming previous generation of ships and aircraft in "bang for buck".

Land warfare is next on the list: https://time.com/article/2026/03/09/ai-robots-soldiers-war/