> 2.86 miles per day is the practical MAXIMUM, given perfect conditions

In your particular setup.

A typical car can expose about 3 square meters of lateral area for those same 8 hours, and receive 3 kW of irradiance. multijunction cells can exceed 50% efficiency, so we're talking about a theoretical upper limit of 12 kWh electric per day.

That would require a vehicle totally covered in cells, including the windows, so not very practical, but adding up to 30 miles/50 km per day is nothing to sneeze at.

We could also imagine all sorts of solar receivers that engage during parking and inflate the apparent surface within the limits available, track the sun etc. to maximize energy.

This is all wrong.

> multijunction cells can exceed 50% efficiency

The maximum demonstrated efficiency of a multijunction cell, in a lab, WITH CONCENTRATION is less than 50%. Commercially available cells are lower.

Concentration is an important caveat for two reasons:

First, it implies that you are collecting light from a larger area than the PV panel itself. Second, efficiency grows with increased irradiance (so efficiency will be lower without concentration).

> 3 square meters of lateral area

Lateral area is meaningless. It’s all about area perpendicular to the solar axis. Unless you are driving a box van or a big pickup truck, there is zero probability that you can put 3 kW of irradiance on your panels. Neither of those vehicles will achieve kWh/mile numbers anywhere close to a Prius.

In practice, you need to halve the efficiency and more than halve the collection area you quoted. You also need to account for conversion losses.

This is a theoretical exploration of the hard limits, not an engineering design.

The multijunction theoretical efficiency limit is 87% with infinite junctions, and over 50% with a practical number of junctions. There's nothing stopping you from creating a miniatural concentrating solar device that focuses the light from a 10 cm^2 area onto a 0.5cm^2 cell, we haven't seen such devices because the cost and extra mass exceed what you get from the efficiency gains when you can simply increase area; a very area constrained application with high power requirements might change that.

> It’s all about area perpendicular to the solar axis. Unless you are driving a box van or a big pickup truck

Again, what stops the top hood and engine cover of a Prius from raising at an angle and tracking the sun, perhaps even unfurl additional area? what about the area of the doors and windows?

Current solar cars can drive 1000 km per day with an average speed approaching 100km/h. It doesn't seem completely out of the realm of the possible to achieve 50km in an hour for a passenger car that can expose similar area while parked.

> This is a theoretical exploration of the hard limits, not an engineering design

You replied to (and even quoted) a comment explaining the practical limits, then doubled-down and said multi junction cells can exceed a number which has never been experimentally demonstrated.

And here you are again saying that multifunction cells can achieve 87% efficiency.

An ICE engine can achieve 100% thermal efficiency with the right Th and Tc. That has about as much relevance to the discussion at hand as 87% efficient solar panels.

Let me be clear: the most efficient cells that have ever been experimentally demonstrated under any conditions are less efficient than the number you originally stated. In real world conditions the number is half of what you originally.

> Again, what stops the top hood and engine cover of a Prius from raising at an angle and tracking the

I guess I’m just feeding the trolls here.

EPA range tends to be pessimistic for EVs as it assumes you are always traveling at highway speeds. Even small reductions in speeds can make EVs much more efficient since drag is quadratic. A quick google search shows Prius prime owners reporting 4-5.5 miles/kwh, so the 3-6 mile range is entirely plausible.

> EPA range tends to be pessimistic for EVs as it assumes you are always traveling at highway speeds.

EV EPA range historically has been overstated. However, the water is muddied because the EPA doesn't really force the manufacturers to give an accurate number. A manufacturer can choose a highway only test, but then also arbitrarily decide to derate the value (EPA example is 70%). A manufacturer can choose to include city driving in the rating and weigh it accordingly and also derate the value (if they want).

Tesla traditionally (still the vast majority of new and used EV market share) has been the only manufacturer that uses the highway + city driving tests. People then get surprised when the car cannot do the full range at 85 MPH.

All in all, this is the EPAs fault. For EVs they really need two numbers, city driving range and highway driving range. EVs are so much more efficient than ICE that speed makes a huge difference given there substantially smaller energy density.

https://www.epa.gov/greenvehicles/fuel-economy-and-ev-range-...

EPA's city cycle speed is an average 19.6 mph, highway speed is an average of 48.3 mph. City range weighted at 55% and the highway range at 45%.

I don't think it's that simple. IIRC you don't have to do the city testing.

https://www.epa.gov/greenvehicles/fuel-economy-and-ev-range-...

Regardless, the EPA test cycles have unrealistically low speed profiles.

Everyone is also glossing over the distinction that regardless of the actual amount, it's not at an actual voltage that can charge the battery to add mileage. You can hypothetically say that because it's offsetting the power usage from the AC that it could theoretically be saving that battery usage...but there's so many gross assumptions being made that it's a pointless statement to make, and it's all out the window the second the car starts the ICE side of the hybrid drive system for even an instant.

> Everyone is also glossing over the distinction that regardless of the actual amount, it's not at an actual voltage that can charge the battery to add mileage.

Neither is the voltage when you plug it in at home. The car has a unit specifically to convert the voltage.

If you're saying they didn't connect the right wires for that, that sucks but is easily fixed.

> it's all out the window the second the car starts the ICE side of the hybrid drive system for even an instant

Nah, doing a drive where it's 99% solar power and 1% "burned an ounce of gas to maintain the engine for the month" is fine.

That article sure has 49 pictures, none of which show more than the very edge of the solar panel.

But looking at some proper pictures, it covers most of the midroof with 7x8 tiles of solar. But you could fit a good percentage, even sticking with a design where a huge amount of the roof into the trunk is all glass. And there are no panels on the hood. So that's an easy doubling right there, more with an average car roof shape.

  >13.6 kWh battery. 39mile EPA range... 915 Wh... 2.86 miles, not 3-6

If we're picking nits, the usable capacity is only 10.5 kWh (11.5 kWh with AC-to-DC losses), so it should be 3.40 miles. Not 2.86, or even 2.62 (= 39/13.6 * 0.915).

I wonder how much extra range you would get if one leaves the car in the shade so that it doesn't get super hot and there is no need to turn on the AC hard? I bet it's more than 2.86 miles.

I believe having a carport and house roof covered with solar panels + (PH)EV is the best option.