Distribution is the real moat. For instance, after I created the FB pages, I had zero followers then decided to experiment with posts made by the agents and see if they performed. I got some impressive results then decided to boost them, currently they have the best Cost per Click I have seen.
Why does everyone think organic is an outlier, niche kind of choice that is done by some isolated, moral farmer in a distant idyllic village? It is as mainstream and commercialized as the alternatives. In fact, nothing separates it from every single purchase where people pay more hoping it makes you feel better and gives your better results.
You'd rather run a crowdfund to lobby for everyone so that chemicals are more regulated in all of agriculture. That way, everyone gets a better baseline, which raises the standards for what is termed as 'organic'.
No yet,but it's a feature that can be added to allow the planning phase have a human in the loop because currently the planning agent handles all the planning,will definitely look into this thanks.
Higgs boson was predicted in theory in 1964, and found in LHC in CERN in 2012-2013. With this, all elementary particles in the standard model of particle physics have been found.
From the 1970s to 2010s, physicists believed in a theory called supersymmetry, which predicted supersymmetric partner particles for the known elementary particles. But these should have been already found in the energies used in LHC.
For the first time, there is no mainstream theory that would predict any new findings. Maybe the next bigger particle collider will find no new particles at all?
A collider produces far more than new particles or explanations. They produce papers and phds. In effect, thier primary goal is to produce stem careers. The new particles are just the public announcements. The collider doesnt even need to be functional. Much/most of the work occures before first light, before anyone turns it on. The design of the ring and its innumerable detectors and subsystems takes decades. So a great many people want the next collider to be funded regardless of its potential for scientific discovery.
The same discussion can happen re the ISS. Its primary purpose was not science. It existed to give shuttle a parking spot, to keep the US manned space program ticking along and to keep a thousand russian rocket people from going to work for rando countries. The ISS will soon end. Are we going to put up a new one? A place to park starliner and dragon? Or are we going to shut down low earth orbit spaceflight? The decision will not turn on the potential for new science, rather it will be about supporting and maintaining a flagship industry.
> thousand russian rocket people from going to work for bad people.
Just like for the Germans before!
I agree with you that it is an educational tool, but if that's all it is, there are cheaper ways to educate that might also have a higher likelihood for scientific discoveries. To build a new collider, we should have some things we're trying to do/find.
>The same discussion can happen re the ISS. Its primary purpose was not science.
But it's worth noting that many experiments took place on ISS covering few domains, examples being AMS (cosmology), CAL (quantum physics), SAFFIRE (combustion), and Veggie (botany/sustainability).
And the LHC did science too. But, in both cases, the amount of science generated was not worth the money and/or the same could have been acomplished at far lower cost via other means.
> Higgs boson was predicted in theory in 1964, and found in LHC in CERN in 2012-2013. With this, all elementary particles in the standard model of particle physics have been found.
Before LHC Large Hardron Collider (CERN), there were other experiments with lower raw and final recorded data rates: SppS (CERN; MB/s; 1-10 Hz), SLC (SLAC (Stanford); 50 MB/s; 2 Hz), LEP (CERN; 100 MB/s; 1-5 Hz), Tevatron (Fermilab (Chicago); 250 GB/s, 100-400 Hz), HERA (DESY; 500 MB/s; 5-20 Hz), LHC CMS/ATLAS (CERN; 40 TB/s; 1000 Hz).
HL-LHC (CERN; 10X LHC;)
FCC-ee (CERN), FCC-hh (CERN)
Non-confirmed non-elementary particles of or not of the Standard Model?
What about Superfluids and Supersolids (like spin-nematic liquid crystals)? Are those just phases? Is the phase chart for all particles complete?
How can they alter humanity? What's the difference for humanity since CERN found Higgs particle? In what ways could the potential dark matter particle detection alter humanity?
It’s a place where extremely skilled people work highly motivated on humanities hardest problems at scale.
CERN pushed distributed computing and storage before anyone else hat problems on that scale.
CERN pushed edge computing for massive data analysis before anyone else even generated data at that rate.
CERN is currently pushing the physical boundaries of device synchronisation ( Check „ White Rabbit“ ), same for data transmission.
CERNS accelerator cooling tech paves the way for industrial super cooling, magnet coils push super conduction…
Companies are always late in the game, they come once there is money to be had:
No one founded a fusion startup until we were close enough to the relevant tripple product.
You are perfectly right, this has been similar to the "space industry" (which includes 'ballistic nukes' knowhow maintainance). The thing with a bigger collider is it seems there are, not that honnest, scientists retro-fitting models in order to reach 'appropriate for this new collider' energy ranges where 'new physics' could be found.
What does that even mean? The FCC is essentially the next plausible energy range we can probe with a collider.
Going larger would cost more, and add risk.
So like, yes? The obvious thing to do is to analyze our models and come up with experiments to do within energy ranges which are plausibly accessible with near future technology.
This is where there is a questionable issue: some network of dishonest scientists may have retro-fitted the models in order to get realitic energy ranges for this new collider.
Sure, but if experimental physics don't matter, wouldn't it be a far better idea to develop all those kinds of technology without actually building the expensive collider itself?
In what way would studying black body radiation alter humanity? Oh just the basis for quantum mechanics and thus transistors, lasers, MRIs, photovoltaics, and more.
The point is, you don't know in advance. I admit it's a bit more far fetched with these experiments that are so far removed from everyday life, but they're still worthwhile.
I understand how linacs and even small compact syncrotrons can have practical medical and industrial applications, and I understand that in the past CERN has developed technology and produced research which is relevant to hardon therapy.
What I don't understand, and maybe you can clarify, is how the very largest gargantuan accelerators can ever have practical relevance. How can effects and products which can only be studied with accelerators that are many miles large ever have application in hospitals unless those hospitals are also many miles large? Not going to lie, I get "NASA invented Tang" vibes whenever this subject comes up; like the medical applications of small accelerators are obvious and parsable to the public, so they are used to sell the public on accelerators the size of small countries.
Because of the engineering effort required to build such systems, that no one has built before, means there is a gigantic amount of R&D discoveries that can be eventually applied in other fields outside particle physics.
Hence why CERN eventually created an industry collaboration office, responsible for finding business partners that would like to make a business out of such discoveries.
The internet existed, hypertext existed, it was just happenstance that it was put together there. It would have happened somewhere, maybe not exactly the same protocol but the same end result.
I disagree that any new possibility for treatments should be lauded. The theoretical side of things is fine, but many new treatments are far more expensive than existing options without offering improved outcomes.
This is orthogonal to your point about CERN being useful.
> Some people also believe praying beats vaccination programs.
> Unfortunately I have got to know people that are only still around me thanks to this technology that you find needless.
There is no way to know whether these people would have been served better by receiving radiation therapy. Your statement is tantamount to believing in prayer.
What do you mean by 'any evidence that works better Than alternatives'?
It can deliver radiations to the brain that will peak at the exact position of the cancer, and reduce irradiation in sane tissues.
The 'better' is 'less irradiation to sane tissues' that in turn reduces the risk for new cancers.
Note: I'm not expert on the matter, but I had technical visits to IBA and know several PhDs that work there
> What do you mean by 'any evidence that works better Than alternatives'?
I mean exactly that, clinical trials demonstrating that proton therapy is superior to radiation therapy. This is not a question about the physics but about how patients respond (and whether the expense of delivering proton therapy outweighs the expected marginal benefits).
But on the subject of discoveries and practical uses, the IBA cyclotrons are also used for other purposes than proton therapy: cleaning exotic fruits from dangerous substances and personalized medicine.
This may be one of the good cases, then. I'm not an expert in cancer but I am a biologist and physician. The head and neck cancer (here) and various pediatric indications get the most attention but it has felt that proton therapy has been seeking an indication for almost 40 years now.
The study was designed to show non-inferiority, which doesn't preclude their ability to show an improvement. It would be helpful to see other studies before determining that proton therapy is better (or even non-inferior) to radiation therapy. It's certainly much more expensive, which shows up in the study as many subjects being denied insurance coverage.
Edit: This is now in the weeds, but the per-protocol participants didn't fare better than the intention-to-treat participants, which one might expect since insurance approval lead to dozens of subjects changing treatment arms.
In Europe at least, many insurances cover it if you have the right criterias.
From my visits, they mostly focus on children that have some very nasty cancers, the IBA hospitals are all designed with children in mind (to avoid stressing them), and from my memory, a unique hospital is often enough to treat a whole country for the kind of cancer they target.
Now, if it is on par with classical radiotherapy BUT it gives less subsequent problems, it might be worth the cost as subsequent problems can be as expensive or even more than the original treatment. It becomes an actuarial issue to know where is the tradeoff.
I think we agree in general, I don't disagree that maybe Proton therapy is not better than radiotherapy, it might but we lack some evidence.
I only argue that if they are equal in quality of treatment and the 'total cost' is the evaluation parameter, it is way more complex than the treatment itself, and it could be justified to use proton therapy, even if more expensive.
Everyone is trying to prolong their life be it by trying to eat healthy, working out and all other ways. Billionaires just try harder than most because they have the means.
Hadaa Ai has been growing steadily and with users increasing, application monitoring and error logging has grown so critical. I decided to built a simple bot that works by subscribing to Rails error reporter and sending me the errors right before they hit the logs. The more silence I see in the channel, the happier I get :)
And rewarding. I guess the issue is, how broad is the problem we are trying to solve? Until there's a narrow, very narrow market fit, products will start or even evolve into sophisticated nightmares.
I like the Obsidian example. Getting started is easy, maybe what we need is a neat way to tuck away complexity and let advanced users choose when to use it.
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