1. The stated range goes down the toilet at motorway speeds. Expected range plummeted from 500km to 300km. Actual range was more like 250km, probably thanks to the cold temperatures. This was a *50%* reduction.

2. We had to plan the trip carefully around chargers. There were 10 minute detours to find chargers, traffic jams at the chargers, and slow charging speeds (probably due to said cold). We tried to charge from about 10% to 80%, but this was taking more than an hour, and shifted to 10% to 60%, which was around 40 mins. Each stop averaged 1+ hour, including the detour, waiting, and charging.

3. There were no chargers at the lodge, and this meant a final charge before ascending the mounting to near 100% to ensure that despite the extreme cold we could make it all the way up and back down. We also wanted to ensure we had extra power in case we got stuck on the road and had heat. This final stop was another hour.

All up, the EV added more than *eight hours* to our round trip. Some of this time might have been spent on toilet breaks and eating anyway, but nowhere near *eight hours.* Bear in mind this was all on a near new Tesla with a near new battery and presumably the fasted possible charge rate and some of the best range available in an EV right now. This is just a huge fail for road trips, and I'm so glad I rented one to find this out before buying.

I'm hopeful battery technology like this makes it into production ASAP. There is so much R&D pouring into batteries right now.

- We were able to make 300km with 90% to 10% battery (to not hurt the battery longevity too much)

- Outside temp was -4 to +2 °C

- Inside temp set to 20°C, seat heating 2/3 for two passengers

- So a we made a charging break every 300km, so approx every 2-3 hours

- Recharging those 80% at a supercharger takes about 30-50min depending on the Supercharger-version.

- We had 0 traffic/wait times at the super chargers (we drove both directions on a sunday)

- We would do a 10-15min break anyway every 2-3 hours to grab a coffee or do magic pee, so the extension of the charging breaks over our normal breaks aren't event that long

- All superchargers had a <5min detour from the Autobahn

Overall we spent approx. 2hrs more on breaks as we would have with a conventional car. I think thats a fair trade-off for 2-3 vacation trips a year, figuring in the time saved for normal refilling stops with a non-EV cars during commutes (when you are able to charge your EV at home).

To me, the future of "driving into holiday fully electric" is already possible with a Tesla LR model. With other EVs without Supercharger-Access/smaller battery/slower charging speeds probably not so much.

You can even save more time by using tools like ABRP[0]. This even gives you better charge-planning with shorter, time-optimized stops also figuring in detour times.

[0]: https://abetterrouteplanner.com/

When you’re driving in the colder parts of Europe it’s generally advisable to keep your tank at least 50% full all the time. If the shit hits the fan, like it did for me in Switzerland once, and you’re stranded for 4 hours due to a crash out of your control, your car becomes a fairly important life support system until the road is cleared. There is no recovery option when there are a few hundred cars in the same shit.

So you’re 3 miles from a supercharger with 15% battery left and your car is a frozen brick in under an hour. You can’t deliver more fuel to it and your efficient route plan is a liability and there’s a queue of bricked EVs waiting for flatbed recovery.

I’m not criticising the concept but the current execution and the perception of it.

There are a few things to consider.

First up, if you want to optimize for energy efficiency then the best option in an EV is to carry a blanket and rely on the seat heaters as much as possible.

Consider this scenario with a long range model 3. 80kwh, 15% means you have 12kWh available (Let's drop that to 8 due to cold weather). The seat heater consumes 500W at low power. That gives you 16/people hours of heat.

But let's say you just run the HVAC straight. You've still got 1 hour of heat (assuming it's using the 6kw restive heater. More if you are using the heat pump).

In any event, the approach to "I'm in an EV and stuck in traffic" is exactly the same as if you were in an ICE with low fuel. Shut things off. Wait until you are freezing, turn it on again. Ration your fuel/energy until you are unstuck.

To get to your charging destination in this scenario, you need roughly .9kwh of energy (300wh / mile, which is on the high end) or about 2% of your battery.

That said, these vehicles are clearly not made for a long haul cold weather existence. Can they be made to work for occasional use with some planning and prayer? Sure. But these stories and the counter-claims leave no doubt that people who park cars in -30F and do 300 mile one-way trips through mountain passes and deserted highways should stick to ICE vehicles. If you're doing some variant of this with regularity (say 0F and occasional 150mile trips), you should probably do the same for safety reasons, even though EV will probably be fine for all but the rarest disaster.

Regardless of ICE or EV, people doing this kind of driving are well-advised to prepare for having a non-functional vehicle. It's always best to stay with the vehicle if it's habitable and if rescue is what you can count on, but having cold-weather gear, food, shelter, means to create/use external heat sources, and ability to "hike out" are some basic rules of the cold road that even 'tourists' should abide by. If you're doing remote winter driving, basically also pack for winter backpacking. This in addition to road flares, small shovel, tow strap, etc. to support the vehicle. It's less necessary now than it was in, say, the eighties when vehicles were far less reliable, but it's still practical advice: be prepared.

I'm guessing this is hyperbole, but really, this is a scenario that does not exist pretty much anywhere outside of Alaska and Russia. And even still, you'd probably be shocked (heh) at how many fast EV chargers present in these locations.

Every year, the situation with EV chargers has gotten better, by a lot. Consider the fact that John Day OR has a fast charger [1].

There aren't many places in the continental US more than 100 miles from a fast charger. Very little prayer is needed, though a bit of planning is nice. It's hard to find a location that you can't comfortably reach with an EV that has 300+ miles of range.

[1] https://www.plugshare.com/location/304770

Considering EV's lose range based on temps, that charging stations are still sparse in hostile environments, that a passers-by can't siphon out fuel for you (I know an ICE can jump start a Tesla, but not sure how practical it is to charge a Tesla from an ICE), ICE engines are still a better bet if you're in such conditions.

https://www.caranddriver.com/news/a38807463/tesla-model-3-cl...

In your example with 15% left, you'll use ~9% battery while in traffic for 4 hours keeping the heat and car on, leaving 6% to get to the next charger. At ~300wh/mile you'll arrive with ~4-5% left. There's also buffer under 0%, but it's not guaranteed.

4-5% is not a comfortable number to be at, but I think it's acceptable in a worst case scenario like this. That being said I would definitely turn down the heat, and drive slower for the next few miles (and check for alternate chargers) to minimize power usage.

I completely forgot that the energy of the outside air is used, that explains it of course.

Heard it the first time when an American from California said it to their kids

I had to stop once for the full 1100km trip to refuel (before leaving Austria on the way back cause it’s cheap to tank there, not because we actually needed to refuel).

It was ~4:30 per way. Nobody in the car had to pee, etc.

I think doing 15 min break per way would have been ok. But doing 1h per way or more if breaks is really not great. Particularly with kids in the car (we leave really early put them as sleep, they woke up for the last 2:30 h or so and that was borderline).

> - Recharging those 80% at a supercharger takes about 30-50min depending on the Supercharger-version.

How is this so totally different to the above commenter? I also need brakes during my rides and after a three hour ride a break sounds totally reasonable. But nowhere between 30 to 50 minutes?

I drove a 'normal' car and he drove a tesla Model 3. He left an hour earlier and arrived 30 minutes after me (with a relatively full battery to avoid the need of destination charging). He has the car for a little over a year so he probably optimized the charging schedule a bit better, but I still wonder why there was such a big difference between his and your experience (1.5 extra hours vs 4 extra hours for a single trip). He did not have to wait at the chargers, so that could account for some of it..

We only stopped for gas, toilet breaks, and took a 15 minute break for coffee and lunch.

1. I drove fast on the Autobahn. I'm usually cruising at 160kph+, and did the same with the Tesla. Doing some homework, this kills efficiency fast. I imagine your brother was driving slower. Probably more within the high efficiency band.

2. Temperature delta. It was -5C + wind chill for most of our trip, and much colder up the mountain.

3. I kept a healthy battery reserve when seeking chargers (10%+) Tesla owners seem to encourage letting the battery drop below even 5% as this means an even faster charge to 60%. I am told there is an optimal cadence to charging which I suppose one perfects over time.

4. I did not conserve heating, as I'm told many EV owners do on longer trips. My wife likes our car to be subtropical.

5. Our Tesla might have been abused, though I recall it having <20,000km.

6. 1,000km is 17% shorter than my trip, further compounding (reducing) these differences.

7. Maybe my regenerative braking was set to low. I didn't think or know to check.

8. My route took me to at least a few regular chargers instead of superchargers. Maybe if I had been smarter and spent more time planning I could have used only super chargers.

9. Perhaps you stopped for a lot of breaks, reducing the relative advantage you might have had in your car.

10. Perhaps he left more than an hour earlier than you.

11. Perhaps my charging lines were longer than his.

I'm sure there are many other factors I'm not considering.

In fact, going such speeds is probably massively inefficient for ICE cars as well, just that they're already incredibly inefficient already that you don't see much of a loss.

On Austrian highways its nominally 130km.

Equation [1]: F(d) = 1/2v^2CdA

Lowering the Cd (drag coefficient) and area can significantly reduce your drag.

[1] https://en.wikipedia.org/wiki/Drag_(physics)

I typically drive at 180-190kph, that’s my “relaxed driving” speed. 160kph is “falling asleep” kind of speed unless you have a super loud car.

160 kph+ (100 mph+) is way past the efficiency sweet spot :)

US interstate speed limits have their roots in fuel conservation for WW2 (or noise control in wealthier spots), safety was just a side effect at least at first.

Minor nitpick: there are 80 and 85mph interstates/sections.

I've lived in a few different states across the US and I've yet to happen across one. (I am an American, yes we all learn metric in school, you can blame Reagan canning the attempt to switch in the 80s)

Edit: https://upload.wikimedia.org/wikipedia/commons/thumb/c/c3/US...

I've not spent much time in any of the dark-green ones (or the blue bit), so that's why.

People with expensive german cars usually go 220kph up to 280kph if they are pushing it. Doing 300kph on safe straight sections is not unheard of, but hard to pull off due to traffic.

I didn’t have to tank for the round trip, but I decided to tank on the way back cause in Austria tanking is much cheaper.

My car isn’t particularly new, but the lowest I’ve seen it use is 4.5l/100km and at 180-190 it uses 6.5l/100km.

In Germany most people don’t drive huge SUVs. Mine is a relatively sleek station wagon.

Reducing the aerodynamic surface of cars significantly improved fuel economy.

Yes, pretty much. I wouldn't say 1.5x is a constant factor.

If I drive at 200+kph (e.g. 240kph) then consumption explodes.

This stuff must be online somewhere, but for me at least it seems that consumption increases exponentially (e.g. x^2), which makes sense since air resistance increases with v^2.

There's a lot of variance that comes into driving an EV on a longer trip.

Very likely. Though more likely is the owner of a Tesla is more apt to the nuances of charging and planning ahead.

I would optimize the car choice for the 90% use of daily commute instead of optimizing for the 3-times-a-year vacation trips.

This, to me, is the worst part of buying an EV right now - the marketing does the Apple "30 hours of battery***" lie and it varies so horribly that it's hard to trust anything about it.

I guess it would be easy if you're just a daily commuter, but I regularly do 800km trips and all projections show that it'll prolong an already long trip for hours.

Driving a car with a (low, not prone to lateral wind effects) trailer is inconvenient but doable when needed.

https://www.motor.no/aktuelt/motors-store-vintertest-av-rekk...

* Norway doesn't have speed limits which go anywhere near 160kph. I was on the Autobahn for most of my trip. How fast were they driving? 50-80kph appears to be a lot more efficient than 160kph.

* Did they drive to maximise efficiency of power or time? I have a heavy foot accelerating.

* Were they using the heater liberally? We were. I'm told this uses a lot of power, especially on models which don't have a heat pump.

* Was brake regen high or low?

For the record, I'm not arguing that the Model 3 can achieve better efficiency than I achieved. I was simply explaining that in my case, it was poor.

Meanwhile, in germany, you have the autobahn...

It is currently -17c where I am. Expected to go down to -28c in the next couple days. A 250km range in winter is simply unacceptable in my area (northernish canada). That is only a couple hours at highway speeds. But the real killer remains the absolute temperature limits on the batteries. If it cannot handle -45c without invalidating some warranty, then it just isn't useable. I cannot afford to spend that sort of money on something that I cannot park outside.

But those outlets mean nothing in term of whether I can buy an EV. If the power goes out then we loose those outlets. Or what if I need to park somewhere without outlets such as at the airport? It is one thing for a car to not start. You can always tow it and warm it up somewhere else. But a car that will take damage if it gets cold is totally unacceptable.

Looking at the current Tesla warrenty: https://www.tesla.com/sites/default/files/downloads/tesla-ne...

I think your info might be just out of date. I don't see any references to specific temps, just normal don't be dumb stuff (like exposing the battery to a fire)

I did find this from 2014 though: https://teslamotorsclub.com/tmc/threads/battery-warranty-and...

This says the warranty at the time said:

• Exposing the vehicle to ambient temperatures above 140°F (60°C) or below -22°F (-30°C) for more than 24 hours at a time”

So it sounds like they took it out eventually?

Do you mean 110..130 km/h EU speeds or 150+ km/h Autobahn speeds?

If you want to optimize for range you should apparently aim for holding a constant 50-55 km/h.

[1] https://teslike.com/

https://cleantechnica.com/2018/07/15/tesla-range-plotted-rel...

- preconditioning the battery & cabin while the car is parked and plugged in

- using one of the newer models with a heat pump

- turn the cabin heat down and the seat heating up

The first point is the most important. We often have little range loss on our way to the destination but significant on the trip home because we couldn't plug in at our destination and the car got cold.

That said, the Volt will warm the system with the ICE if it gets below -10C. But I've heard similar numbers from pure-BEV owners.

I think rather 80-90 km/h, at least for Nissan Leaf, as well as from the table you linked (55 mph ~~ 89 km/h)

However, for newer EVs the sweet spot will be at higher speeds, because those cars are able to recharge at much higher speed (at least 2 times faster).

The table doesn't show any data below 55 mph. This site: https://cleantechnica.com/2018/07/15/tesla-range-plotted-rel... has a graph that plots range vs speed all the way to 0 (for the Model S) and it shows the 'optimal' speed to be around 35 mph.

Lived in Germany several years and it was not unusual to get wild game cross the street at the worst times. Most Authobahn have protections against, but some parts are badly maintained and I have seen some crossings...

"Wild Boar Crash Test Highlights Growing Accident Risk" https://www.spiegel.de/international/zeitgeist/road-carnage-...

In 2010 for example... "...A total of 27 people died and 3,000 were injured in a quarter of a million collisions with wild animals on German roads in 2009, not to mention the hundreds of thousands of animals that perished in the process..."

Notably it’s lower energy density by weight, but not substantially by volume.

YMMV, but what enabled this:

- it takes a bunch of time to shuffle kids through bathrooms

- overnight hotel charging

- we didn't eat in the car

With a gas pump, you need to stay with the car while it's filling. With an electric, you can eat/bathroom/sleep. If you're doing a long trip with a family and want to stay sane, you need to budget time for that stuff anyways.

Is that a realistic concern for anyone? The "charging" process at a gas pump takes around 1 minute (in Europe gas pumps have ~50 l/min flow rate, in the US it's 10 gal/min). At best you can get a battery recharge in 20min but more realistically today over 30min for 80% charge if the charging station hasn't reached peak charging capacity and starts lowering charging speeds for everyone.

Usually the longest wait is during holiday season where at the middle of the highway everyone needs to fill up around the same time/place and queues form. This is not something EV tech can help with intrinsically, if you don't wait today it's because there aren't enough EVs on the road.

Once most cars on the road are EVs wouldn't you have the exact same issue with queuing at busy charging station in holiday season? This will be exacerbated by the fact that charging takes longer than 1min, and too many cars charging at the same time would most likely lead to a drop in the overall charging rate of all cars in the station (it's unlikely charging station will support high-speed on all chargers simultaneously).

The way we drive and refuel now revolve around the concept of the quick refill gas pump. We need to adjust our expectations, driving style/planning/habits, and technology - induction charging roads, "third rails", things that address any shortcomings of EVs, not just adapting old solutions to new problems.

> We need to adjust our expectations, driving style/planning/habits

Before I was married, I had a diesel car with a 1000km range. I made that 3000km trip in 36 hours total, which I never could have done with an EV car. Driving that far that quickly by myself without stopping to rest more was reckless and stupid, so not being able to do so is a significant side benefit.

It's up to the operator. When cars are smart enough they might even disconnect after a preprogrammed charge and move to a waiting area.

Edit. Updated currency for clarity.

> With an electric, you can eat/bathroom/sleep.

With an electric, you can eat/bathroom/sleep because it takes so long that those things become possible. Yes, you can't sleep in the three minutes it takes to fill the gas car.

I don't stay with the car during fillups on road trips though, I start the fill and run into the convenience store to stock up on snacks and by the time I'm back 2-3 minutes later the tank is full and I can be back on the road.

That's illegal in many jurisdictions, like Pennsylvania. It's dangerous everywhere. Those click off latches aren't infallible, gasoline filling needs to be supervised. You don't have to stand there -- wash your windows or check your oil.

Buy and use an EV for all the easy daily stuff, then rent something more suitable for the yearly/less frequent long trip. Other than range we have a similar problem with space, for big trips we end up with tons of stuff and more space is useful but day to day less so. So the 90% EV could be smaller as well and still solve the problem.

I do see the attraction of having one thing that solves 100% of the uses though.

If Tesla wants to get people who are more budget conscious or who will depend on their vehicle as a single car family then they need to really up their parts and repair game. I don't want to buy a John Deer EV that spends most of it's time at the dealer getting fixed until the warranty runs out.

Since it is a fixed capital expenditure, you need suficient EVs on the road for it to make economic sense, but from that point forwards it's a no-brainer compared to stuffing every vehicle chock-full of rare minerals for the unlikely case of a ski trip to Austria.

I think the thing that's lacking right now (despite political will) is standards for electrified roads. I like the general approach that Sweden is using, with rails embedded in the road surface: https://www.youtube.com/watch?v=VZNHZnyxCm8

[1] https://www.treinreiswinkel.nl/reizen/autotrein

[0] https://www.lis.energy

It's likely to be for the foreseeable future given that net zero otherwise requires carbon capture equal to the extracted fossil fuels, and we seem to be some way off effective carbon capture let alone cost effective carbon capture.

So mass transit does more lift than EVs in terms of carbon neutrality. Not to mention noise pollution and tire particulates causing asthma.

Is that enough to make electric cars viable for all use cases? It depends on cost --- of the car initially and of a battery replacement. It would have to be less than the cost of current electric vehicles which have a much longer expected battery lifetime.

If I were an average American driving an average amount and I charged my car every night it would be topping the battery from 97% to 100%. Does that qualify as a cycle? I don't know, but I doubt it. Even if I recharged once per week that would be 80% to 100%, and I would also doubt that qualifies as a cycle.

The authors estimated 10 year lifespan but I'm not sure how they came up with that number, either. If these batteries really do offer 5x density I would likely charge my car 30-40 times per year.

My wife plugs her phone in every night as a matter of habit --- just to be sure, whether it really needs charging or not. I know from experience that this degrades the battery lifetime.

[1] https://support.apple.com/en-us/HT210512

Smart charging would be: "start charging now and finish at time my alarm is set, while reaching 80% battery." Slow charging to 80% and your battery can last multiple times what it would "normally". I don't understand the craze for 40-60-100 watt phone chargers...

I've discontinued the automation and will just buy a new battery in another year or two instead. /shrug

If you’re always topping off the charge at night, the cells in the battery pack are still experiencing full discharge cycles eventually. (Cells will end up staying at 100% charge for a while though, which is probably ultimately bad for them, but they should still be fully discharged/charged eventually…)

However, many drivers do a bunch of 500+ miles drives per year; 1, 10, or 100, depends on the driver.

At 500+ miles, battery anxiety starts to kick in.

An electric car that combines current high-cycles-low-range batteries with a smaller low-cycle-very-large-range battery for those 10 500+ miles trips per year would be a killer product. We are talking here 1000+ miles without charging, which is kind of much farther than what most cars can get without re-fueling.

I do maybe one 500+ miles trip per month. That'd be ~24 cycles / year, such that these batteries would have a lifetime for my use of ~40+ years. That's more than enough for me.

There are a bunch of companies working on hybrid battery designs that combine different technologies to serve different purposes. Some of them are already hitting 800+ miles in real-world tests.

I have a Tesla model 3, it's got a decent nav system, is aware of the battery state, current trip, average speed and the like. For me it makes range anxiety a non-issue. I had a 1200 mile road trip, did no preplanning, just filled the car with luggage and family, hit nav, and said "navigate to <1200 mile distant city>".

The Tesla experience is pretty transparent and the superchargers are pretty frequent and reliable. I've yet (over 30k miles) expected to charge at a supercharger and not been able to.

Generally I had more than one place I could stop and once charging it would give feedback like "charge x minutes to reach next charging station with 15% battery left". Sometimes we'd charge a bit extra waiting on someone and it would automatically pick a further charging station. While driving the car would helpfully say things like "You'll arrive at the next charging station with 15% battery left if you keep under 75 mph". Despite going through of some of the lowest density charging areas like eastern Nevada or southern Wyoming I had no issues.

The charging stations I used were quite close to the major highways, and the strategy we used was to fill up to 50-75% and recharge when we had 10-20% left. This involves more stops, but also maximized charge speed, often 550 miles/hour or more. Charging slows as the battery gets more full. With 3 people and a dog the car was generally ready for departure about as quickly as the rest of us.

I did however carry power adapters for 120v, 220v, and the popular J1772 just in case, haven't used them, except when it's free like at some Universities (like Stanford) or businesses (like 2 hours free at Target).

The car can't possibly know if the owner is planning a 500 mile trip the next day. The only "safe" approach is to assume they are and top up all batteries every time it is plugged in.

If the owner plugs it in every day, how does this impact the usable life of this new battery?

The car operator may not always know when it's necessary --- assuming he is not psychic. He may just top up to be on the safe side.

* If you are someone who doesn't want to worry about not going to 100% all of the time the new iron based batteries (featured in base model 3 right now for instance) don't care, you can let those sit at 100%, and they are safer too. The downside is less total range range and/or more weight.

Someone who drives infrequently (a senior for example) or has multiple cars could easily leave a car plugged in for days.

It also helps the battery when it gets cold, the car will use power to help keep battery warm, which also helps increase battery life.

How this will impact their definition of "cycle" is unknown but again; based on my experience with batteries, it won't be good.

Charging every night for a 5 day week, from 80% to 100% is 1 cycle (in this crude example).

A cycle is not the number of times you plug in a battery to charge, it's a single charge/discharge full to empty and vice versa.

There is more to it of course because you never really "empty" a lithium battery, and for longevity it may be configured to never be fully charged to 100%, but that's roughly the point.

Yes, most rechargeable batteries will degrade over time just sitting there --- without any "cycling".

And it's easy to overlook the most important factor for general applications - price - where the declines are much more dramatic.

People complain about the lack of progress with batteries but we've observed that EV range has doubled in 8 years. I see no reason that range wouldn't double again in the next 8 years - and I see plenty of reasons for that to happen.

[1] https://pubs.rsc.org/en/content/articlehtml/2021/ee/d0ee0268...

If you asked me if organic polymers could resist the growth of metal dendrites, I probably would have said no, because plastics creep like crazy, and metal dendrites are hard and sharp, so over time they will inevitably win unless they stop growing. But lithium is soft like cheese, and Kevlar's creep resistance is comparable to steel's. Maybe this is why Wang and Emre are publishing groundbreaking material science in Nature Communications and I'm not.

- Nissan Leaf 62 kWh battery: 410 kg= 6.61 kg/kWh

- order of magnitude for this type of battery: 1.32 kg/kWh

- power consumption: @15 kWh/100 km

- 100 km requires 15 kWh, or ~19.80 kg

If something like this in order of magnitude comes true, hand luggable batteries will be able to cover non-trivial distances. Some potential consequences:

- I imagine something like this could help enable a low-end, more maintainable second hand market in a not-so-distance future.

- For inhabitants of terraced town houses, this could enable them to charge their batteries at home too. Hand luggable batteries could simplify _a lot_ in terms of charging infrastructure.

- Exceptionally far trip? Throw in a few extra modules.

I'm not your how safe that would be, nor would I really want to be charging a 15kWh+ battery inside my home if I lived in a terraced house as GP suggests.

As others have stated, kevlar is also used in all sorts of other applications. The material can come from wherever.

Unless poster is talking about 4680 batteries, which are going to be used in production cars in Q1 or Q2 2022. But those are 20-30% more efficient/cheap compared to the 2170 form factor

There's a pending 4680 improvements widely expect to ship in the Texas gigafactory model Y this quarter, time will tell. I believe this is generally on the announced schedule.

Am I missing something? Tesla batteries seem to be delivering on promises and experts in the area seem impressed with the Tesla battery reliability, performance, longevity, and kwh/$. Some to the point of calling Tesla a hugely successful battery company that includes various packaging for their batteries in the form of power walls, and model 3/y/x/s.

So he promised it for a couple of years and so far he's been off by about 2 years from the first "promise" shown in that video.

Talking about how 90% of highway miles could be done with driver assist is not a promise and it's not self-driving. Not sure why dishonesty is required to attack Musk, there's plenty of material available.

— The White Queen, Through The Looking-Glass by Lewis Carroll (1871)

If such new battery tech makes it possible to deliver high capacity batteries with smaller lifecycles, they'd make great add on batteries. Imagine if there was a standard way to say place an extra battery pack in the trunk or the front trunk for the long trips to give an additional 400 KM range!

For now, if I buy an electric car, I should simply account to pay for a rental gas car for those road trips for the sake of convenience. I'm sure many people do road trips with 45 min breaks every three hours or so, and not be anxious about availability of charging slots or even a functional charging point, but it is not for everyone.

Unfortunately, the long trips are often the trips where you really want the full luggage capacity.

For myself it's living in a 1st floor apartment, with price being secondary, and maybe concerns over the charging network in the UK at the fringes being third. I don't think range would be a big concern.

I want an EV that can pull off this 315 mile trip without dipping into reserves, even in the winter. I expect we'll get there in a few years, and I'm willing to pay a bit extra for that battery.

Do you set a departure time so the car and batteries are at the optimal temperature?

If you charge under 25% I'd expect to charge at 550 miles per hour at a supercharger (again nav there so the car knows to arrive at optimal temperatures), so if you charge around 275 miles I'd expect another 100 miles in 10-11 minutes. If it's bitterly cold I'd expect another 10 minutes or so.

Shouldn't take anywhere near 45-60 minutes unless something is seriously wrong.

Additionally charge cycles generally means full charges, so 1000 full charges = 10,000 charge of 10%. Similar rules apply to any similar battery technology, like in an apple laptop or pretty much any cell phone.

For more data points check out: https://electrek.co/2020/06/06/tesla-battery-degradation-rep...

From what I can tell various improvements in battery management and chemistry things have improved things since the above post.