Feral-deer

the hart of the forest

1. The court holds Google responsible for statements made by its AI, considering them Google's statements (search engines have limited liability for results in their engine as they're the words of other sites/companies/people), meaning when their AI lies/hallucinates they're liable for the defamation/harm resulting from those statements.

2. Google's defense that customers are generally aware of the lack of reliability and are responsible for fact checking was dismissed. As the court pointed out, that would "significantly diminish" AI Search's stated purpose and it can't be distinguished from Google's business practices/statements as a search tool.

3. Studies have found about 91% of Google's everyday AI responses are accurate, leaving millions of searches per HOUR with potential liability for falsehoods. 56% of correct responses weren't supported by the sources the AI listed. Both of which mean Google is now liable for a LOT more AI "errors."

4. Google was held liable for 80% of court costs in this case and this precedent is expected to reverberate around the world. This is a massive shift from the 3rd-party search provider role Google has previously played and it comes right as they've tied ALL searches to their AI search.

For all the reasons above AND ALSO because this particular lawsuit is a defamation case

Privacy lawsuits are hard because most privacy laws are super super weak, and there's very rarely a lot of money or enforcement backing privacy laws for...twenty million reasons, really...

But defamation suits? Those have teeth.

(In large part because, at least in some countries and including in the US, defamation laws protect public figures the least - and "public figures" legally includes most if not all politicians, and a hell of a lot of other rich ppl too)

A German court has ruled that Google can be held directly liable for false claims made by its AI Overviews, a decision that could put a serious legal dent in the whole “the AI made me do it” defense. According to The Next Web, the Regional Court of Munich issued a temporary injunction after Google’s AI Overviews wrongly tied two Munich publishers to scams, subscription traps, and dubious business practices. The court treated those AI-generated summaries as Google’s own statements, not just ordinary search results pointing to third-party pages. That distinction matters. Search engines have traditionally had more protection because they index and link to other people’s content. AI Overviews changes the machinery. Google is not just showing the web anymore. It is summarizing it, rewriting it, and sometimes apparently hallucinating a tiny legal grenade into the results page... This is still a preliminary injunction, not a final ruling, and Google can appeal. But for publishers, brands, SEOs, and anyone watching AI search swallow the results page, the message is clear: if Google wants to be the answer engine, courts may start treating it like the publisher of those answers.

Over fifty years of data show a peak in PFAS (also known as "forever chemicals") content in seabird eggs in the 90s, followed by a decrease as regulations went into effect. The most recent findings show a 70% decrease of most common PFAS.

We are making genuine progress! Producers are dramatically altering how much they use PFAS and how much gets released in effluent, but also there's a lot better understanding of how to remove PFAS from the environment!

you can think of this sort of like how water wicks into a paper towel. the water gets stuck to the paper because it's attracted to it via capillary forces, even though there's no chemical reaction going on.

the two main methods used are granular activated carbon (GAC) adsorption and ion exchange (IX).

activated carbon is already pretty familiar to a lot of us; it's the stuff in a lot of replaceable water filters. the activated carbon has a huge internal surface area, and that allows for the fairly weak intermolecular forces to add up and allow contaminants to get "stuck" onto the surface of the activated carbon. over time, the activated carbon gets filled with junk, and you have to replace it.

GAC is essentially this, except that the activated carbon is granularized and produced in specific ways to maximize how much it attracts certain chemicals. this can be tuned because activated carbon gets its massive surface area from internal "pores", and various processes will change how large and frequent those pores are.

It's essentially a Russian nesting doll of pores, and controlling the size of the larger pores influences the permeability of the activated carbon and controlling the size of the smaller pores (micropores) influences what exactly is most attracted to the activated carbon.

However, GAC has a few major downsides:

It is not specific to PFAS. This is more of a mixed blessing because it was already frequently used and well understood, and the infrastructure for producing and distributing it already existed. However,

It loses effectiveness over time and must be replaced. This is a continued cost, albeit a low one, but this has one final major issue

As time goes on, the PFAS previously adsorbed to the activated carbon is desorbed and replaced by other things that have a higher affinity for the activated carbon.

As such, ion exchange (IX) was always very compelling. The whole point of it relies on the fact that PFAS molecules are predominantly made of two parts: An acid head group (either a carboxylic or sulfonic acid group) and a perfluorinated tail.

The head groups on the right are what become ionized—or specifically, deprotonated. A hydrogen leaves and is replaced with a metal cation (usually sodium), forming a PFAS salt (chemical meaning of salt!). These are much more soluble in water because of polarity reasons, and so the mobile PFAS molecules are almost always in that salt form.

By passing through these PFAS salts through a permeable polymer matrix that has (1) numerous positively charged groups like quaternary amines and (2) highly mobile negative ions loosely attached to those stationary positive groups (most often chlorides), you can actually get the PFAS to be "stuck" inside the polymer matrix and what comes out is just good ol' sodium chloride, or salt (culinary meaning of salt!).

This shows a version with hydroxide (OH-) ions as the mobile anion, but it's the same idea. The +NR3 in yellow are stuck to the polymer matrix, but the OH- can freely move around. However, without another anion to replace the OH-, the ionic attraction prevents the hydroxides from leaving.

In comes the PFAS. Despite being slightly soluble in water, the anionic PFAS aren't really that mobile, and when they pass through, it's much easier for the hydroxide ions to leave. Another very important effect is that the long perfluorinated tail of the PFAS is attracted to the polymer matrix, whilst the counterions are ONLY attracted via the ionic force. Thus, PFAS would much rather hang out in the polymer matrix.

Of course, IX has its own downsides

These resins are much more expensive, both to manufacture and to transport.

While they can be "regenerated", it's a tricky process that currently requires the use of nearly anhydrous methanol, which is both poisonous and extremely flammable, increasing the operating costs.

As the hydrophobic tail is a key part of allowing the PFAS to stick to the matrix, short-chain PFAS are very poorly dealt with by this system. This is exacerbated by competition between different PFAS molecules, as long-chain ones will cause short-chain ones to desorb.

Overall, the best method appears to be using a series of ion exchange resins followed by an activated carbon filter. The ion exchange will capture the bulk of the PFAS molecules, and the activated carbon will grab any stragglers. Effective filtering of other contaminants prior to the PFAS removal system will also ensure minimal competition in the activated carbon.

Also a welcome reminder that just because a Big Problem doesn't seem practically solvable right now doesn't mean it won't become solvable in the future!

So from then on whenever one of us called something problematic, he would make us talk it out until we could name the “bad” thing we were hinting at. In this particular class, 7/10 it was some type of oppression, and the remainder was like, “I’m uncomfortable because this is very new/confusing/pushing boundaries that made me feel safe.”

Once we stopped calling things “problematic” and stopping at that, class got way more interesting and... we all had to say, like, “that’s racist” or “that’s misogynistic” or “ew capitalism gross” out loud, which a lot of us had never done in a classroom before. Or we had to be like, “Uhhh... I’m not sure what’s so bad?” and confront our own beliefs and that was maybe even more useful.

• hydrate it by drinking lots of water

• eat dark chocolate and blueberries and walnuts and salmon and other foods high in antioxidants!!

• play little brain games on your phone; I like wordconenct! anything that makes you think!

• read books. It’s simple but necessary. Even better - join a book club, or read with a friend, so you can have discussions after. This will improve your reading comprehension.

• do puzzles - it doesnt have to be sudoku, I love playing Beat Saber on the Oculus Rift because it makes my brain have to match colorful patterns to physical movements very quickly!

• learn a new dance - even a tik tok trendy dance. Learning new dance moves are proven to strengthen synapses!!

• go bird watching, or foraging, or anything outdoors that requires you to explore pattern recognition and visual searching

• watch a movie with the intent of analysis - this is best done with a cinephile friend!! talk about tropes and symbolism and character growth

• cross stitch, or sew, or do anything that requires matching nimble hand movements to patterns

• play or learn an instrument!

• develop a consistent sleep schedule (or as close to consistent as you can get!)

• when eating, try to identify the ingredients and flavors you’re perceiving!

[The Legend of Zelda: The Wind Waker - Gamecube]

The game has been modified in the following ways in this gif:

Today’s Shy Guy’s of the Day is:

Desalination is the process of generating freshwater from brackish or saltwater, usually through the process of reverse osmosis. While this can be a very useful tool in water shortages, it also has some pretty huge drawbacks--reverse osmosis requires a lot of energy, requires chemical treatment of the water, and produces concentrated brine as a waste product which can be harmful to aquatic ecosystems.