Load bearing: will solar+gas be cheaper than gas alone?

The costs to power a real-world load โ€“ e.g., a data center โ€“ with solar+gas will often be higher than via a standalone gas CCGT in the US today. But not internationally? Or in the future? This 9-page note shows how solar deflation and load shifting can boost solar to >40% of future grids.


Solar deflation has been amazing. The costs of utility-scale projects have fallen by 75% in the past decade, via rising module efficiency and manufacturing scale, and we see costs falling to $400/kW and 1-3c/kWh in the future (per pages 2-3).

However the LCOEs quoted above are only on a partial electricity basis, assuming an idealized offtaker that happens to consume power, always and only when a utility-scale solar project happens to generate, which in turn features hour-by-hour volatility, day-by-day volatility, season-by-season volatility and even year by year volatility.

System costs depend on the system, which can have different load requirements and ability to load shift, ranging from from loads at, say, data centers to e-LNG plants.

The LCOEs for energizing a 100MW round-the-clock load, with 70% gas and 30% solar (i.e., solar+gas) are compared and contrasted with a standalone CCGT, in the case study on pages 4-5.

The LCOEs for energizing a more flexible load, with 60% gas and 40% solar (solar+gas) are compared and contrasted with a standalone CCGT, in the case study on pages 6-7.

The numbers depend on gas prices and solar capex, and vary interestingly in different geographies and contexts.

The “optimal” share of solar to meet real-world loads are discussed on page 8. And maybe in future, there will be demand sources that scale up in the energy system that really are designed to absorb all and only solar output profiles, per our sci-fi fantasies here.

Our long-term forecasts for global electricity and global useful energy see both solar and gas gaining share, due to the economics above.

LNG plant compressors: chilling goes electric?

Cost build-up of LNG refrigeration via gas drive, CCGT electric drive, and renewable electric drive.

Electric motors were selected, in lieu of industry-standard gas turbines, to power the main refrigeration compressors at three of the four new LNG projects that took FID in 2024. Hence is a major change underway in the LNG industry? This 13-page report covers the costs of e-LNG, advantages and challenges, and who benefits from shifting capex.

Energy transition: solar and gas -vs- coal hard reality?

This 15-page note outlines the largest changes to our long-term energy forecasts in five years. Over this time, we have consistently underestimated both coal and solar. Both are upgraded. But we also show how coal can peak after 2030. Global gas is seen rising from 400bcfd in 2023 to 600bcfd in 2050.

Ten Themes for Energy in 2025?

This 11-page report sets out our top ten predictions for 2025, across energy, industrials and climate. Sentiment is shifting. New narratives are emerging for what energy transition is. 2025-30 energy markets look well supplied. The value is in regional arbitrage, volatility, grids, AI and solar.

Kardashev scale: a futuristic future of energy?

Possible uses of basically free solar energy.

A Kardashev scale civilization uses all the energy it has available. Hence this 16-page report explores ten futuristic uses for global energy, which could absorb an additional 50,000 TWH pa by 2050 (60% upside), mainly from solar. And does this leap in human progress also allay climate concerns better than pre-existing roadmaps to net zero?

Cool concept: absorption chillers, data-centers, fuel cells?!

Working principle of absorption chillers

Absorption chillers perform the thermodynamic alchemy of converting waste heat into coolness. Interestingly, their use with solid oxide fuel cells may have some of the lowest costs and CO2 for powering and cooling AI data-centers. This 14-page report explores the opportunity, costs and challenges.

Grid-forming inverters: islands in the sun?

The grid-forming inverter market may soon inflect from $1bn to $15-20bn pa, to underpin most grid-scale batteries, and 20-40% of incremental solar and wind. This 11-page report finds that grid-forming inverters cost c$100/kW more than grid-following inverters, which is inflationary, but integrate more renewables, raise resiliency and efficiency?

Energy transition: losing faith?

Global CO2 equivalent emissions by source projected up to 2050

What if achieving Net Zero by 2050 and/or reaching 1.5ยบC climate targets now has a <3% chance of success, for reasons that cause decision-makers to backtrack, and instead focus on climate adaptation and broader competitiveness? This 14-page report reviews the challenges. Can our Roadmap to Net Zero be salvaged?

Solar trackers: following the times?

A solar tracker improves solar generation by 25%

Solar trackers are worth $10bn pa. They typically raise solar revenues by 30%, earn 13% IRRs on their capex costs, and lower LCOEs by 0.4 c/kWh. But these numbers are all likely to double, as solar gains share, grids grow more volatile, and AI unlocks further optimizations? This 14-page report explores the theme and who benefits?

Energy transition: the triple challenge?

Energy transition is a triple challenge: to meet energy needs, abate CO2 and increase competitiveness. History has now shown that ignoring the part about competitiveness gets you voted out of office?! We think raising competitiveness will be the main focus of the new administration in the US. So this 15-page report discusses overlooked angles around energy competitiveness, and updates our outlook for different themes. ย 

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