During the Cold War, the Good Idea Fairy set various US and Soviet workers to the task of building an aircraft engine using nuclear fission as the heat source. I haven't thought very carefully about how difficult such a development task might have been, but some workers at KAIST have some new interest in a nuclear gas turbine. They appear to intend to use it in a closed cycle in a small modular reactor, and there's no indication that they've any interest in putting it on an aircraft, but the attached figure grabbed my attention.To be fair, the main thrust of the linked article is to claim that a supercritical CO2 power cycle in which the turboexpander adds heat as the pressure drops in order to approximate isothermal expansion would be more efficient. Which is true and relevant. But that figure...
The funny thing is that the paper is about perfectly sensible sCO2 heat engine cycles. "Wouldn't it be great if you could use turbines for an isothermal compression/expansion process?" they ask. The fissionable stators are just weird and out of place, unless South Korea is planning on a 6th generation super stealth high endurance combat aircraft and hasn't told anyone. For any other purpose you'd just use a heat exchanger, as exemplified in any of the experimental examples of quasi-isothermal turbines...
The former RamGen Rampressor rotary supersonic inlet compressor design could be an alternative for the compressor side, though that originally was for CO2 and not supercritical CO2, and most definitely has a high heat rise which may be unattractive. I believe there were mentions somewhere on NSF on heat pipe cooled turbine blades for conventional jet turbines, so ostensibly the fixed stator design would potentially be an good fit for using heat pipe methods bring heat from a separate reactor as a substitute for directly fissioning stators. It looks like a radial grid pattern though if following the pattern of Frontline Aerospace's IsoCool compressor stator vane cooling concept, so manufacturing a uranium fuel stator will either be casting or perhaps a 3D print via laser? I wonder if that becomes easier with just the ring component of the stator vane grid being uranium fuel in simple symmetric airfoil shapes, while the radial vanes (which need proper blade shaping to move flow to the next turbine blades) could be made of something else?Digging a little into the papers, there is mention of a theoretical axial compressor design for supercritical CO2 (apparently that still isn't a thing) in the following reportWang, Yong, et al. Aerodynamic Design of Turbomachinery for 300 MWe Supercritical Carbon Dioxide Brayton Power Conversion System. MIT-GFR-015, 2005But that doesn't seem to be available online?