U.S. Department of Energy

A Small-Particle Solar Receiver for High-Temperature Brayton Power Cycles

SDSU logo Illustration of a rounded-top shape with red and blue dots inside and arrows on the outside.

This conceptual schematic shows a small particle solar receiver. Concentrated radiation from the heliostat field is absorbed directly in a gas-particle suspension rather than on the receiver walls. The carbon nano-particles oxidize as they transit the receiver, resulting in clear gas stream exiting toward the turbine.

San Diego State University (SDSU), under the 2012 SunShot Concentrating Solar Power (CSP) R&D funding opportunity announcement (FOA), is demonstrating a new receiver design that uses air as the heat-transfer fluid. The university's innovative small-particle heat-exchange receiver (SPHER) uses carbon particles to enhance performance and achieve higher thermal efficiency.


The SDSU research team is working to design, construct, and test a revolutionary, high-temperature solar receiver in the multi-megawatt range that can drive a gas turbine to generate low-cost electricity. The goals of this project are to:

  • Validate the SPHER concept by demonstrating for the first time a pressurized solar receiver with a window greater than 1 meter in diameter
  • Produce a reliable, low-cost, high-efficiency, high-temperature receiver approaching the 5-megawatt scale capable of powering a gas turbine for electricity production
  • Prove the capability of the receiver to generate pressurized, high-temperature air at high efficiencies via prototype testing at the National Solar Thermal Test Facility at Sandia National Laboratories.


The concept of a volumetric, selective, and continually replenishable absorber is entirely unique. SPHER uses a dilute suspension of carbon nanoparticles dispersed in air to absorb highly concentrated solar flux volumetrically inside a windowed pressure vessel—rather than on a solid surface as in most other receivers. The small-sized particles rapidly transfer heat to the surrounding air and then oxidize as temperatures increase. A hot, pressurized, clear gas stream consisting almost entirely of air with a small amount of CO2 is then available to drive a gas turbine or be used for a process. This system can readily be hybridized with natural-gas plants.

Publications, Patents, and Awards

At this time, this project does not have published articles, patents, or awards.

SunShot logo

The SunShot CSP R&D program seeks to accelerate progress toward the cost target of $0.06 per kilowatt-hour through novel and revolutionary research into CSP technologies. Learn about other DOE competitive awards for concentrating solar power research that are in progress.