Update files at 2024-02-15 22:17:07

index.html

@@ -231,8 +231,7 @@ <h2>Research Engineer</h2>
         <div class="section">
             Hello! Thanks for visiting. I am a mathematically-oriented research engineer, with over a decade of
             expertise in software engineering, machine learning and quantum computation. Generally, I work on projects
-            involving the science, engineering and characterization of information processing systems. I am currently a
-            member of the technical staff at essential.ai.
+            involving the science, engineering and characterization of information processing systems.
         </div>
 
         <div class="section">

papers.html

@@ -318,6 +318,23 @@ <h3><a href="http://arxiv.org/abs/2203.05520v2" target="_blank">Opportunities an
 unknown frequency over a very wide bandwidth.</p>
 </div>
 
+<div class="paper">
+    <h3><a href="http://arxiv.org/abs/1901.08035v3" target="_blank">Demonstration of a Parametrically-Activated Entangling Gate Protected
+  from Flux Noise</a></h3>
+    <p><strong>Authors:</strong> Sabrina S. Hong, Alexander T. Papageorge, Prasahnt Sivarajah, Genya Crossman, Nicolas Didier, Anthony M. Polloreno, Eyob A. Sete, Stefan W. Turkowski, Marcus P. da Silva, Blake R. Johnson</p>
+    <p>In state-of-the-art quantum computing platforms, including superconducting
+qubits and trapped ions, imperfections in the 2-qubit entangling gates are the
+dominant contributions of error to system-wide performance. Recently, a novel
+2-qubit parametric gate was proposed and demonstrated with superconducting
+transmon qubits. This gate is activated through RF modulation of the transmon
+frequency and can be operated at an amplitude where the performance is
+first-order insensitive to flux-noise. In this work we experimentally validate
+the existence of this AC sweet spot and demonstrate its dependence on white
+noise power from room temperature electronics. With these factors in place, we
+measure coherence-limited entangling-gate fidelities as high as 99.2 \(\pm\)
+0.15%.</p>
+</div>
+
 <div class="paper">
     <h3><a href="http://arxiv.org/abs/1806.08321v2" target="_blank">Quantum Kitchen Sinks: An algorithm for machine learning on near-term
   quantum computers</a></h3>
@@ -344,23 +361,6 @@ <h3><a href="http://arxiv.org/abs/1806.08321v2" target="_blank">Quantum Kitchen
 baseline.</p>
 </div>
 
-<div class="paper">
-    <h3><a href="http://arxiv.org/abs/1901.08035v3" target="_blank">Demonstration of a Parametrically-Activated Entangling Gate Protected
-  from Flux Noise</a></h3>
-    <p><strong>Authors:</strong> Sabrina S. Hong, Alexander T. Papageorge, Prasahnt Sivarajah, Genya Crossman, Nicolas Didier, Anthony M. Polloreno, Eyob A. Sete, Stefan W. Turkowski, Marcus P. da Silva, Blake R. Johnson</p>
-    <p>In state-of-the-art quantum computing platforms, including superconducting
-qubits and trapped ions, imperfections in the 2-qubit entangling gates are the
-dominant contributions of error to system-wide performance. Recently, a novel
-2-qubit parametric gate was proposed and demonstrated with superconducting
-transmon qubits. This gate is activated through RF modulation of the transmon
-frequency and can be operated at an amplitude where the performance is
-first-order insensitive to flux-noise. In this work we experimentally validate
-the existence of this AC sweet spot and demonstrate its dependence on white
-noise power from room temperature electronics. With these factors in place, we
-measure coherence-limited entangling-gate fidelities as high as 99.2 \(\pm\)
-0.15%.</p>
-</div>
-
 <div class="paper">
     <h3><a href="http://arxiv.org/abs/1706.06562v2" target="_blank">Parametrically Activated Entangling Gates Using Transmon Qubits</a></h3>
     <p><strong>Authors:</strong> S. Caldwell, N. Didier, C. A. Ryan, E. A. Sete, A. Hudson, P. Karalekas, R. Manenti, M. Reagor, M. P. da Silva, R. Sinclair, E. Acala, N. Alidoust, J. Angeles, A. Bestwick, M. Block, B. Bloom, A. Bradley, C. Bui, L. Capelluto, R. Chilcott, J. Cordova, G. Crossman, M. Curtis, S. Deshpande, T. El Bouayadi, D. Girshovich, S. Hong, K. Kuang, M. Lenihan, T. Manning, A. Marchenkov, J. Marshall, R. Maydra, Y. Mohan, W. O'Brien, C. Osborn, J. Otterbach, A. Papageorge, J. -P. Paquette, M. Pelstring, A. Polloreno, G. Prawiroatmodjo, V. Rawat, R. Renzas, N. Rubin, D. Russell, M. Rust, D. Scarabelli, M. Scheer, M. Selvanayagam, R. Smith, A. Staley, M. Suska, N. Tezak, D. C. Thompson, T. -W. To, M. Vahidpour, N. Vodrahalli, T. Whyland, K. Yadav, W. Zeng, C. Rigetti</p>