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Here comes the sun: explosion in solar power beckons Updated for 2026

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Is solar power the technology of the future? It is certainly the fastest-growing energy generation technology in the UK.

By the early 2020s, according to a new report, it will be cost-competitive with gas and coal power. If so, the goal of having unsubsidised renewable energy is in sight.

The report, by Berlin-based think tank Thema1, concludes that this is possible without radical technology improvements or similar step changes. This somewhat disagrees with similar studies, which tend to point to the next big thing as being just around the corner.

There are lots of exciting developments in the laboratories but to make a real difference they need time – more than the 10-year time frame in Thema1’s forecasts, so their report is right not to factor them in.

Bright hopes

The majority of new technologies focus on the photovoltaic (PV) module itself, promising higher power output per unit (by using graphene or nanotechnologies) or much reduced production costs (using novel materials like organic solar cells).

Higher rates of converting light into electricity (‘efficiencies’) are always welcome in new PV devices, but their viability depends on the production costs. It is possible today to produce cells that can convert as much as 46% of the sun’s power into electricity, but costs render these commercially unfeasible. The incumbent technology, wafer-based silicon PV modules, converts about 22% of sunlight – at a fraction of the cost.

On the other hand, there is a lot of excitement around technologies such as organic solar cells that are less efficient but have much reduced costs. But this approach tends to shift the balance of costs from the module to the other system components such as mounting structures and can make the system more expensive.

To be commercially viable, these devices need a minimum efficiency of about 10%-12%. This recently led to the demise of virtually all thin-film silicon manufacturers, for example, which struggled to get the double-digit efficiencies in cost-effective production times.

The reality is that the road from laboratory cell to a full-size module is surprisingly difficult and slow. This can be seen when looking at current polysilicon thin-film technologies and how long it took them to come to their current competitive position.

There is no reason to believe that other technologies will be much luckier.

The missing ingredient – political will

Having said this, the Thema1 report is right to say that PV can achieve the costs required to survive – without subsidies, and without any step change in technology. All it needs is the political will.

If governments offer sufficient subsidies in the short term, solar will cut costs just by doing things better. This was the underlying idea of solar subsidies all around the world in recent years.

Yet Thema1 suggests that all we now need to do is incrementally reduce these subsidies, and by 2020 we will have learned how to do things at the market price. This is not completely impossible, but there are some major caveats.

The reductions to UK subsidies of recent years are in fact one of the biggest issues in the industry at present. There were step cuts in funding that incentivised developers to rush through solar projects before cut-off dates, which resulted in installation gluts. This has been detrimental for the quality of installations, resulting in higher operation and maintenance costs and thus higher energy costs.

Governments might argue that subsidy reduction has happened each year and is therefore foreseeable, However, this ignores the fact that these ‘cliffs’ result in a rushed building phase to meet the deadlines.

Reductions typically occur in April – so most building happens in the first quarter of the year, when the weather affects ground conditions and can drive up costs. Changing this hard funding cliff to a softer decline and shifting the timing to later in the year may actually make a noticeable difference in system costs.

The cost of connections is another major issue in the UK, especially with larger developments. The connection cost is sometimes nearly as expensive as the system itself – clearly rendering the investment impossible.

This may be down to weaknesses in the grid and should be addressed on a national scale. All new technologies for producing electricity have required major grid investment, so saying such moves are too expensive for solar is a bit of a smoke screen.

Time of day pricing could optimise PV production profile

Solar PV has the problem that the amount of power it produces varies during days and seasons. One of the most talked-about solutions is to include local electricity storage, which certainly could make solar more competitive provided it can be done reliably and at low cost. But this is may not be required in the medium term.

One reason is that people make the mistake of looking at technologies in isolation. There have been studies in Germany that indicate that this variability can be offset by using wind and solar together, for example. One would need to look at the combinations for the UK to see if this is true in this country as well.

It is also worth pointing out that subsidies are paid to renewable electricity irrespective of the time of generation, although it is more valuable to have an even production throughout the day – with no strong midday peak.

If rates were redistributed to include a timing element, it could be a way of cutting the system cost of PV energy without having to improve the technology itself, as developers adjusted the orientation of their panels to maximise revenue rather than gross production.

But the strongest factor that has the power to make or break solar power is the political support – or lack of it. PV still does have an amazing cost-saving potential through technological progress – as well as through measures like those mentioned above.

But all those together and you have a future that looks very sunny indeed. It is no exaggeration to say that incentive-free solar really could be on the horizon.

 

 

Ralph Gottschalg is Professor of Applied Photovoltaics at Loughborough University.

This article was originally published on The Conversation. Read the original article.

The Conversation

 




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Solar power is getting cheaper quicker than the IPCC thought Updated for 2026

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IPCC figures are already out of date when it comes to the price of solar photovoltaic (PV) power generation, according to analysis by the Fraunhofer Institute.

The numbers suggest that the IPCC’s capital expenditure figures for solar PV – provided in a minimum / maximum range to account for the variations from country to country – are actually higher than recent figures for key regions, including Germany, China and the US.

This matters because policymakers will compare the costs of reducing emissions using solar and other technologies in the coming negotiations to reach a global climate deal.

So why are the figures somewhat overstating the cost of solar? Usually when calculating and comparing the cost of energy generation options – which the IPCC do all the time – the levelised cost of electricity (LCOE) is used.

This the overall cost of each unit of power, and accounts for all the costs involved in generating the power: capital expenditure, operating costs, maintenance etc.

The Fraunhofer Institute has also been calculating the cost of different energy generation technologies for a number of years – levelled out to account for startup costs and subsequent operation and maintenance.  

The most expensive bit – starting out – actually costs less now than the IPCC reports

It found the IPCC’s most recent levelised costs of electricity for solar may be based on much higher capital expenditure costs than is currently the case. Put simply, solar panels have got cheaper.

That means the ‘overnight capital expenditure’ of solar PV is significantly lower, both for small-scale, distributed models such as rooftop solar and for larger-scale solar infrastructure such as a solar thermal plant.

For example, you would only have to spend between $1,500-4,900 per kWp for rooftops installed with solar PV if you were using the Fraunhofer figures (on average), compared to the IPCC’s $2,200-5,300, which refer to the 2012 situation.

The figures fall even further when looking at utility-scale solar PV (think fields, with panels, and maybe sheep, or geese). The institute calculates that now, to start a solar plant the cost would be $1,300-3,300, rather than $1,700-4,300 as the IPCC had reported.

David de Jager, Managing Consultant at Ecofys and Operating Agent for the IEA-RETD agrees that the IPCC’s costs for solar are already outdated.

“Costs of solar photovoltaics have been declining so fast, that almost any publication will be outdated at the moment the ink has dried”, says de Jager who was involved with the IPCC report’s energy chapter as a Contributing Author. “The growing market will drive further cost reductions even further.”

Both minimum and maximum costs from the Fraunhofer ISE are lower than the most recent IPCC estimates from 2012, for both utility and rooftop capital expenditure.

Overall average cost levelled out across the life of the project is therefore also too high

If the capital expenditure figures are outdated, then the LCOE figure will also be calculated on an inaccurate basis, particularly because the capital expenditure for renewables is higher than fossil fuels like gas.

Economically it follows too that the cheaper installation gets, the cheaper the cost of solar gets overall, because of the much lower (and steady) operation and maintenance costs.

If the capital expenditure is higher than it should be, the levelised cost in solar-producing countries will also be higher.

The Fraunhofer institute have calculated the average cost of generating power from solar panels in a range of countries using the latest data. The ‘median’ cost of solar from the IPCC report is at the higher end of their LCOE values.

The IPCC looked at literature reflecting a wide range of PV-applications and regions. If you look at the key markets today, the study shows that PV costs are already at or below the low end of the range presented by IPCC.

Money for solar is cheaper too

Borrowing costs may also have been overstated by the IPCC, says Fraunhofer.

The IPCC uses a uniform 10% weighted average cost of capital so as to be able to compare costs across different energy generation methods which has a large impact on renewables because of their large up front capital costs.

Because the costs of borrowing capital in many parts of the world is cheap at the moment due to low interest rates – and certainly in places like Germany and the UK  – this number may also therefore inflate the cost of installing solar.

In fact, loan finance for solar installations is readily available at 5% or less – half the assumed interest rate.

However it’s impossible to verify the PV cost figures actually used in the most recent IPCC report, published last weekend, as no actual figures are quoted. Rather, assumed costs are opaquely woven into ‘scenario’ models.

 

 

Helle Abelvik-Lawson blogs for Greenpeace UK. Her background is as an academic in energy and human rights, and she now reports on global energy issues.

This article was originally published by Greenpeace.

http://www.greenpeace.org.uk/newsdesk/energy/analysis/how-solar-power-getting-cheaper-quicker-ipcc-thought

 




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Costs of living in a nest Updated for 2026

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Male of the harvestmen Zygopachylus albomarginis (with yellow ink marks) inside his mud nest, while a female approaches from the outside [Credit: Gustavo S. Requena]

Male of the harvestmen Zygopachylus albomarginis (with yellow ink marks) inside his mud nest, while a female approaches from the outside [Credit: Gustavo S. Requena]

Nests are extremely important for males’ fitness when reproduction and parental care are associated with these structures. The possession of a nest and its conditions may determine male attractiveness (due to female reproductive decisions) and offspring survival (due to protection against adverse biotic and abiotic conditions). Nest construction and maintenance, however, may also impose costs to males: nest-related behaviors may demand time and energy or may increase mortality risks. The costs and benefits approach is usually used to understand the evolution and maintenance of behavioral traits, and we explored this framework in a study with the Neotropical harvestmen Zygopachylus albomarginis.

 

During the breeding season, nesting males of Z. albomarginis spend several months building, repairing, cleaning and defending their mud nests. After mating, females abandon the eggs under the protection of males, who actively defend them against predators and fungal infection. Although nest defense, nest maintenance, and offspring protection contribute to different components of males’ fitness, they are performed concomitantly and entail similar behaviors. For instance, when a nesting male chases away a conspecific individual, he defends the possession of his nest at the same time he protects the offspring against a potential egg predator (see video below). Moreover, nest maintenance requires males to remove debris and prevent fungal growth inside the nest, actions that also contribute to protect eggs against infection.

 

VIDEO: [Credit: Gustavo S. Requena]

 

In our Early View Paper “Lack of costs associated with nest-related behaviors in an arachnid with exclusive paternal care”, we quantified the costs of nest-related behaviors in Z. albomarginis under natural conditions. Because males are mainly constrained to forage in a small area close to the nest for up to five months, we expected high energetic costs of being associated with a nest. However, we did not find any evidence of decline in the physical conditions of nesting males over time. Interestingly, males may spend several days eating fungal hyphae growing inside their nests, which we suggest constitutes an important food resource to stationary individuals and compensates for energetically costly activities performed for so long periods.

 

 

At the left, we can see a male inside his nest on a fallen trunk without fungus infestation. At the right, the trunk is covered by fungus fruiting bodies, except inside the nest. Nest-cleaning behavior maintains hygienic conditions inside the nest at the same time it provides food to the male, which feed upon the fungus hyphae. [Credit: Gustavo S. Requena]

At the left, we can see a male inside his nest on a fallen trunk without fungus infestation. At the right, the trunk is covered by fungus fruiting bodies, except inside the nest. Nest-cleaning behavior maintains hygienic conditions inside the nest at the same time it provides food to the male, which feed upon the fungus hyphae. [Credit: Gustavo S. Requena]

 

Due to contest injuries over the possession of a nest or its conspicuousness, we also expected high mortality risks associated with nest-related behaviors. The survival probabilities of stationary nesting males, however, were higher than the probabilities of vagrant individuals not associated with nests surviving. This pattern of differential mortality dependent on Z. albomarginis movement activity may be explained by the potential higher chances of encountering predators while moving, particularly walking among trees and crossing the leaf litter.

 

Given that females lay eggs exclusively inside nests and the costs of nest maintenance and defense are extremely low (if not absent), the million dollars question is “why do not all males have a nest?” Males add salivary secretions to the mud at the moment they build the nests. One possibility, therefore, is that the production of such secretion is costly and only males in good body condition would be able to invest in nest construction. Although the costs of performing this activity was not evaluated in our study, the fact that vagrant males may occupy an empty nest or even aggressively attack a nesting male and take over his nest suggests that some individuals rely on usurpation as an alternative reproductive tactic to acquire nests.

 

 

Male resting inside his nest, which contains several black eggs (indicating advanced embryonic development) [Credit: Gustavo S. Requena]

Male resting inside his nest, which contains several black eggs (indicating advanced embryonic development) [Credit: Gustavo S. Requena]

The authors through Gustavo S Requena

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