Nuclear is actually the only baseload option.
I have never understood the 'wind power' concept, as it fundamentally can't work.
The electricity infrastructure in every country requires two main classes of generation:
1) 'Base Load'
This produces a continuous, high level of efficient power generation, 24 hours a day. It can't react to changes in load very quickly because it's made of very big devices - it may take half an hour for a given plant to take up the slack.
However, the size means that each plant is very efficient - big transformers, big rotors etc. mean that the energy gets from the axle to the grid with extremely small losses.
2) 'Peaking' or 'Surge' plants.
These produce relatively small amounts of power 'on demand', to cover for surges in demand (eg when everyone makes a cup of tea in the commercial break of a popular TV programme). They have to respond in seconds or minutes at most - a system might have some plants that respond in seconds, with other taking over a few minutes later if the surge is prolonged.
The surge will either drop back to base load, or it will continue (eg when offices and factories open at the start of the day) and the operators decide whether to ramp up the 'big iron' or to let the peakers take the strain.
Regardless of which technologies are actually in use, these are the two kinds of generation required.
Coal and Nuclear fit easily into the Base Load class.
Hydroelectric is unique in that it can go into either class depending on the design, but is more commonly seen in the Peak class - eg
Dinorwig pumped storage in Wales.
Some forms of Micro-generation can fit into the 'Peak' class, but only if it can be turned on quickly when required.
Wind doesn't fit into any of these sections.
In fact, the only place Wind could be of use, is combined with a pumped storage system and used when available to pump the water.
So, which 'green' technologies exist to take the base load?
Nuclear, Nuclear and, erm, Nuclear. It has built-in 100% capture (unlike coal etc) and doesn't require the flooding of massive areas (unlike baseload hydro).
In some places Geothermal can be used, but there aren't many countries that have a sufficiently low demand and enough geothermal available for it to be worthwhile.
As for solar - sorry, but photovoltaic cells are currently
damaging to the environment, because it takes so much energy to make them. A few years ago, they took more energy to make than they would
ever generate in their useful life. While this has improved, they're still pretty terrible.
Solar furnaces appear to work reasonably well, but they're pretty hard to maintain and use a lot of space. There are large experimental ones in southern Spain and France, but they're currently quite low yield.
- They work best in sunny climes, which tend to be rather dusty.
The Seville solar furnace plant is expected to generate approx. 11 MW when it's finished. By comparison, each of the four Calder Hall nuclear reactors in Sellafield generated 50MW when turned on in 1956.
All of this is set to become much worse, because so many people are keen on electric vehicles - they've got to be charged somehow.
In fact, hydrogen (or other manufactured combustible)-powered vehicles make much more sense than pure electric because of the charging problem. It's much easier to take a tank full of fluid around and pump it into vehicles as required than to try to charge big sets of batteries.
(edit to add)
Some people argue that charging massive numbers of electric vehicles would remove the need for 'peaking' generators, as the charging can be speeded or slowed to 'manage' the load and smooth it out, but that still means that we need a *lot* more baseload!
