The Extended Range EV (EREV aka plug-in hybrid) is the straightforward answer to this.

I agree, the whole limited range issue has been so over-hyped. Once you adjust your lifestyle, it really isn't a problem. How often do you need to go farther than the daily range of a Leaf? Hardly ever. And if you do, you take a break at a public charging station along the way, or heaven forbid, borrow an ICE-powered car! I sometimes drive hundreds of km in a day, with only a few hours of top-up midway. Not an issue at all.

increasing efficiency and electrification will reduce these to sufficiently small niches that synthetic fuels (from renewable power, not biofuels) will work just fine.

I disagree with that comment, however, since there are thermodynamic efficiency limits that we are very close to now. We could probably shave a little bit off in the future but this would require lots of additional energy just to build out this new, marginally more efficient infrastructure. In a time of plenty of oil, that might be feasible. But since the US in particular is frantically running out of oil, I don't think it will be so straightforward. Furthermore, future economic and population growth from 6 billion people wanting a western lifestyle will suck up those efficiency gains.

130 years ago, kerosene was needed for illumination, and then electric lighting made it obsolete.
And where did that electricity come from?

40 years ago many homes in the US were heated with heating oil - the number has fallen by 75% since then.
And what fossil fuel took heating oil's place?

US cars increased their MPG by 60% from about 1976 to about 1991.
How many more cars were there in 1991 vs. 1976? How much oil and fossil fuels did it require to manufacture this new more fuel efficient car fleet?

50% of oil consumption is for personal transportation - this could be reduced by 60% by moving from the average US vehicle to something Prius-like.
Since the US imports over half of the oil it burns (a highly unsustainable situation -- this WILL end in the not-too-distant future), then a complete transition to hybrids (who is going to pay for all of them? How long would it take?) could maybe reduce that so the US imports ONLY 1/4 of its oil...

oil consumption ... could be reduced by 90% by going to something Volt-like. It could be reduced 100% by going to something Leaf-like.
Not at all. How many of the parts in a Leaf are made from oil? Actually, a better way of phrasing that would be to ask how many parts AREN'T made from oil? Rubber? Wire insulation? Anything plastic or synthetic? Paint? How about all the coal and natural gas (and oil) needed to mine and refine all the raw materials (where does steel come from?). How much fossil fuel is needed to produce the electricity to charge the Volt? I know that you will counter-argue that wind, solar and nuclear will be able to power this in the future. Well, when the sum of all of those energy sources breaks past 1% of energy supply, then maybe I'll entertain the marginal plausibility of your fantasy of being able to power a modern industrial society at levels similar to today, without fossil fuels.

We don't need oil (or FF)
I used to think that too. Then I really looked at the numbers.

As Alan says, best hopes for the transition.

Easy to see how you conclude that
Europe is currently stuck between a rock and a very hard place.

Even though you do exclude all countries with falling demand and all oil exporters your core group still retains some of the largest European economies. I wonder if the US would offer up any grouping of states that show flat oil demand in the same period? And I wonder how useful it would be to group them in such a way?

Price of heat pumps: my heat pump from Vaillant with 8 kW (Vaillant geotherm 81/2) has cost around 7000 EUR without heat source but with installation in 2007, the 6 kW variant would habe been around 6200 EUR, the new generation has higher COP and better circulation pumps, prices have only slightly increased. I paid for my ground source almost 4000 EUR due to stupid planning, a better trench solution would now be possible for 2000 EUR. So a ground source heat pump is possible in Austria or Germany for 10000 EUR or less.

My electricity demand is 4500 kWh for household, 2500 for heat pump and my heat demand for my well isolated house (170/200 sqm) is 8000 kWh for room heating of these 5000 kWh in Dec.-Feb., 2500 kWh for water for 4 persons. During summer (April-September) it takes 60 kWh per month to provide hot water for 4 persons with my heat pump (performance is around 4), therefore, small losses of a potential PV array are negligible.

It is obvious with the numbers above that a fuel cell with 50% electric efficiency would give much too much electricity in winter, so a combination with heat pumps in other houses in my neighbourhood would give a much better situation. In summer PV would be the obvious solution when batteries become cheaper. A solution with only fuel cells is IMHO not useful. Older houses have a higher heat demand in winter, therefore, produce even more problems.

CO2 heat pumps with better heat source than air have again a two times better efficiency in central Europe, this means for me that the higher costs of the ground source is still the more economic solution in the long run esp. when the ground source lasts for 60-100 years.

My house has a peak demand of 5.5 kW at a outdoor temperature of -15 °C, the (stupid) idea was to get a special heat pump tariff which, however, allowed the utility to stop delivery during peak times (max. 6 hours per day) therefore the 8 kW heat pump. The result now is that I save around 20 EUR per year compared to an alternative with higher priced household electricity but have wasted this with higher capital costs (800 EUR difference of 8 kW HP vs. 6 kW HP means 50 EUR more capital costs. :-(

There are some duff comparisons out there.
A lot of people have fallen in love with the idea that they can put solar panels on their roof, get of the grid and run their car on that too, and so don't fancy fuel cells which they see as big oil trying to retain its grip.

The killer for solar is always annular variance, as daily can be coped with, although the storage needed costs money.
Here are the figures by town around the world for solar incidence:
http://www.gaisma.com/en/location/chicago-illinois.html

This page is for Chicago, which illustrates some of the problems with this notion outside of the tropics and maybe places like Arizona with either a steady supply of sunshine or supply peaking pretty well with demand, and not having a harsh winter with a heavy heating load as Chicago does.
Insolation in Kwh per day per square metre drops from 6.04 in July to 1.50 in December.

It would be tough to power your car and house, which would both have a very high draw in cold winter weather that way without a massive, and massively expensive, overbuild.

Things are a whole lot easier for hydrogen/methane etc as they are storage mediums in themselves.
The German natural gas network contains, I was surprised to learn, several months worth of supply.

The supposed difference in efficiency just aren't there, or at any rate not nearly as great, as commonly supposed anyway.

The Leaf gets around 3.4miles/kwh measured at the wall (ibid)
That is 294watts/mile.

The typical efficiency of the US grid, which has an average of 7% transmission loss kicking around in the figures, is around 33%.
That efficiency is unlikely to go up much anytime soon, as powering up and down fossil fuel plants to cover intermittent renewables hits efficiency at any given level of cost.

So that is 882wh/mile worth of power used

The Toyota FCEV, which is a bigger car than the Leaf, used in regular driving on regular roads gets 68mpge:
http://www.nrel.gov/hydrogen/pdfs/toyota_fchv-adv_range_verification.pdf

Taking a kilogram of hydrogen at 40kwh, that is 588wh/mile

Using 60% for natural gas reformation and compression we come out to around 980wh/mile

Transmission losses in natural gas/hydrogen delivery are a small fraction of that in the grid.

Battery only advocates then hypothesises all sorts of things, such as that sustainability means that the efficiency of producing electricity should be taken as the most efficient way possible, by using combined cycle gas turbines, which hit perhaps 65%, although of course you would still have transmission losses.

Actually, and this is something that the discussion in this thread has made me realise, the most efficient way would be to use that power that our German friend would have to throw away in a home fuel cell.

An electric car for 12,000 miles a year would use around 3,500kwh, which would put a dent in his surplus electricity in winter, and transmission losses would be minimal.

In Germany though with its excellent public transport most car journeys are long distance, which is a lot easier in a fuel cell car.

Further out battery only advocates argue that the losses involved in using electrolysis make fuel cells way less efficient than taking their energy straight.

Those arguments are somewhat self serving,in my view, as hydrogen can utilise resources such as stranded wind, and either concentrated solar or nuclear can use otherwise wasted heat in thermochemical reactions which puts the efficiency way up.

I don't know what the mix will be, but using the suite of technologies available, including fuel cells and batteries, I am confident that transport can be maintained, although I agree with the thesis of this site that oil will get scarcer and more expensive.

That is not to say that there will not be bumps on the road, however!