Heat exchanger configuration with porous layer

What is claimed is: 1. A heat exchanger for a nuclear reactor, comprising: a hot flow channel; a cold flow channel fluidically separated from the hot flow channel; a mixing control; and a porous thermally insulative layer disposed between the hot flow channel and the cold flow channel, the porous thermally insulative layer comprising: an inlet; an outlet; and a fluid pathway between the inlet and the outlet; and wherein the porous thermally insulative layer is configured to flow a control gas formed by a mixture of two or more gasses through the fluid pathway, and wherein the mixing control is configured to change the mixture of the control gas to vary a thermal energy transfer efficiency of the porous thermally insulative layer. 2. The heat exchanger as in claim 1 , wherein the control gas is used for leak detection of a first fluid, a second fluid, or both. 3. The heat exchanger as in claim 1 , wherein the control gas is used to capture a fission product or an activation product. 4. The heat exchanger as in claim 3 , wherein the control gas captures tritium. 5. The heat exchanger as in claim 1 , wherein the control gas comprises argon and helium. 6. The heat exchanger as in claim 1 , wherein the porous thermally insulative layer is formed of a metal or metal alloy and defines an open pore structure. 7. The heat exchanger as in claim 1 , wherein the porous thermally insulative layer is formed through an additive manufacturing process. 8. The heat exchanger as in claim 1 , wherein the porous thermally insulative layer reduces a thermal energy transfer efficiency from the hot flow channel to the cold flow channel. 9. The heat exchanger as in claim 1 , wherein the heat exchanger is a plate heat exchanger comprising a hot plate and a cold plate and wherein the hot flow channel is formed as first guide channels in a surface of the hot plate and wherein the cold flow channel is formed as second guide channels in a surface of the cold plate. 10. The heat exchanger as in claim 9 , wherein the porous thermally insulative layer is disposed between the hot plate and the cold plate. 11. The heat exchanger as in claim 1 , wherein the porous thermally insulative layer decouples the hot flow channel and the cold flow channel and allows the hot flow channel and cold flow channel to react independently to a thermal gradient placed across the heat exchanger.