tweaks

_performancehighlights/connectomics.md

@@ -4,7 +4,7 @@ layout: highlight
 theme: dark
 permalink: 'features/aurora-performance-highlights/connectomics'
 
-title: 'Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks'
+title: 'Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks'
 pi: 'Nicola Ferrier, Argonne National Laboraotory'
 award: 'Early Science Program'
 systems: '-'

_performancehighlights/cosmictagger.md

@@ -6,8 +6,6 @@ permalink: 'features/aurora-performance-highlights/cosmictagger'
 
 title: 'High-Energy Particle Physics at Scale: CosmicTagger'
 pi: 'Corey Adams, Argonne National Laboratory'
-award: '-'
-systems: '-'
 
 image: 'Adams-cosmictagger.png' 
 

_site/features/aurora-performance-highlights.html

@@ -517,7 +517,7 @@ <h1 class="page-title">Aurora Performance Highlights</h1>
   	</div>
   	<div class="content-wrapper">
       <small class="eyebrow"></small>
-  		<h3>Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks</h3>
+  		<h3>Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks</h3>
       <small class="meta">PI: Nicola Ferrier, Argonne National Laboraotory</small>
   	</div>
   </a>

_site/features/aurora-performance-highlights/connectomics.html

@@ -3,9 +3,9 @@
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-<title>Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks | 2023 ALCF Annual Report</title>
+<title>Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks | 2023 ALCF Annual Report</title>
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@@ -16,9 +16,9 @@
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@@ -431,7 +431,7 @@ <h2>
 
 
 
-    / Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks
+    / Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks
 
 
 </div>
@@ -466,7 +466,7 @@ <h2>
 
 </div>
 
-	<h1 class="page-title">Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks</h1>
+	<h1 class="page-title">Brain Connectome Reconstruction at Scale: Large-Scale Connectomics with Flood-Filling Networks</h1>
 
 
 	<!-- 

_site/features/aurora-performance-highlights/cosmictagger.html

@@ -503,11 +503,6 @@ <h1 class="page-title">High-Energy Particle Physics at Scale: CosmicTagger</h1>
 	</p>
 
 
-		<p class="meta--pair">
-			<span class="meta--name">AWARD</span>: 
-			<span class="meta--val">-</span>
-		</p>
-
 
 
 

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_site/index.html

@@ -350,8 +350,8 @@ <h1 class="title">
 
 <div class="home--hero-caption">
 	<small>
-		Visualization of particle light cone data from Farpoint, a high-resolution cosmology simulation at the gigaparsec scale.
-		<span class="credit">Image: ALCF Visualization and Data Analytics Team and the HACC Team</span>
+		Researchers from the University of Dayton Research Institute and the Air Force Research Laboratory are using ALCF supercomputers to shed light on the complex thermal environment that hypersonic vehicles encounter. This image shows the contour of gas velocity along an experimental test article.
+		<span class="credit">Image: ALCF Visualization and Data Analytics Team, Air Force Research Laboratory, and University of Dayton Research Institute</span>
 	</small>
 </div>
 

_site/science/highlights/grover.html

@@ -545,7 +545,7 @@ <h1 class="page-title">First-Principles Simulation of Hypersonic Flight</h1>
 		<small class="caption">
 			Contour of gas velocity along an experimental test article.
 
-				<span class="credit">Image: ALCF Visualization and Data Analytics Team; University of Dayton Research Institute</span>
+				<span class="credit">Image: ALCF Visualization and Data Analytics Team, Air Force Research Laboratory, and University of Dayton Research Institute</span>
 
 		</small>
 

index.md

@@ -38,13 +38,13 @@ title: Argonne Leadership Computing Facility
 
 <div class="home--hero-caption">
 	<small>
-		Visualization of particle light cone data from Farpoint, a high-resolution cosmology simulation at the gigaparsec scale.
-		<span class="credit">Image: ALCF Visualization and Data Analytics Team and the HACC Team</span>
+		Researchers from the University of Dayton Research Institute and the Air Force Research Laboratory are using ALCF supercomputers to shed light on the complex thermal environment that hypersonic vehicles encounter. This image shows the contour of gas velocity along an experimental test article.
+		<span class="credit">Image: ALCF Visualization and Data Analytics Team, Air Force Research Laboratory, and University of Dayton Research Institute</span>
 	</small>
 </div>
 
 
-
+ 
 
 <div class="home--features-wrapper">
 	<div class="content-wrapper">