diff --git a/Exec/science/Detonation/README.md b/Exec/science/Detonation/README.md
index 77235b01bd..3e0ed244b8 100644
--- a/Exec/science/Detonation/README.md
+++ b/Exec/science/Detonation/README.md
@@ -1,7 +1,7 @@
-# detonation
+# `Detonation`
 
-A simple carbon detonation.  The reaction network should be set
-through the GNUmakefile.
+A simple (carbon or helium) detonation.  The reaction network should
+be set through the GNUmakefile.
 
 This sets up a domain with a uniform density (dens).  A large
 temperature (T_l) is placed in the left side of the domain, and an
@@ -24,9 +24,25 @@ shockwave (as seen in the pressure field).
 Note: if the domain is too small, then the burning will decouple from
 the shock wave, and you will not get a detonation.
 
-Some important inputs files:
+## Inputs files
+
+Some important inputs files
 
 * `inputs-det-x.nse` : this produces a nice detonation that gets hot
   enough for the ash to be in NSE.
+
 * `inputs-det-x.subch_base`: this produces a He4 detonation using the
-same initial condition in the shell burning stage of the subchandra problem.
+  same initial condition in the shell burning stage of the subchandra
+  problem.
+
+
+## Publications
+
+This problem setup has been used in the following papers:
+
+* *A Framework for Exploring Nuclear Physics Sensitivity in Numerical Simulations*
+
+  Zhi Chen, Eric T. Johnson, Max Katz, Alexander Smith Clark, Brendan
+  Boyd, & Michael Zingale, 2024, Journal of Physics: Conference Series,
+  2742, 1, 012021 (DOI: 10.1088/1742-6596/2742/1/012021)
+