Publications

Morrison, Benjamin M.; Landahl, Andrew J.; Lobser, Daniel L.; Rudinger, Kenneth M.; Russo, Antonio R.; Van Der Wall, Jay W.; Maunz, Peter L.

Abstract not provided.

Maunz, Peter L.; Blain, Matthew G.; Clark, Susan M.; Landahl, Andrew J.; Lobser, Daniel L.; Morrison, Benjamin M.; Pehr, Jessica M.; Revelle, Melissa R.; Rudinger, Kenneth M.; Russo, Antonio R.; Ruzic, Brandon R.; Yale, Christopher G.

Abstract not provided.

Hogle, Craig W.; Maunz, Peter L.; Stephens, Jaimie S.; Young, Kevin C.; Lobser, Daniel L.; Revelle, Melissa R.; Yale, Christopher G.; Pehr, Jessica M.; Blume-Kohout, Robin J.; Stick, Daniel L.; Clark, Susan M.

Abstract not provided.

Hogle, Craig W.; Clark, Susan M.; Stephens, Jaimie S.; Young, Kevin C.; Lobser, Daniel L.; Revelle, Melissa R.; Yale, Christopher G.; Pehr, Jessica M.; Blume-Kohout, Robin J.; Stick, Daniel L.; Maunz, Peter L.

Abstract not provided.

Maunz, Peter L.; Clark, Susan M.; Hogle, Craig W.; Haltli, Raymond A.; Lobser, Daniel L.; Pehr, Jessica M.; Revelle, Melissa R.; Ruzic, Brandon R.; Yale, Christopher G.; Blain, Matthew G.

Abstract not provided.

Maunz, Peter L.; Clark, Susan M.; Hogle, Craig W.; Haltli, Raymond A.; Lobser, Daniel L.; Pehr, Jessica M.; Revelle, Melissa R.; Ruzic, Brandon R.; Yale, Christopher G.; Blain, Matthew G.

Abstract not provided.

Stephens, Jaimie S.; Clark, Susan M.; Young, Kevin C.; Blume-Kohout, Robin J.; Hogle, Craig W.; Maunz, Peter L.

Abstract not provided.

Maunz, Peter L.; Clark, Susan M.; Landahl, Andrew J.; Lobser, Daniel L.; Revelle, Melissa R.; Rudinger, Kenneth M.; Yale, Christopher G.

Abstract not provided.

Clark, Susan M.; Hogle, Craig W.; Lobser, Daniel L.; Revelle, Melissa R.; Yale, Christopher G.; Pehr, Jessica M.; Stephens, Jaimie S.; Young, Kevin C.; Blume-Kohout, Robin J.; Stick, Daniel L.; Maunz, Peter L.

Abstract not provided.

Hogle, Craig W.; Proctor, Timothy J.; Blain, Matthew G.; Haltli, Raymond A.; Lobser, Daniel L.; Revelle, Melissa R.; Ruzic, Brandon R.; Yale, Christopher G.; Young, Katherine T.; Maunz, Peter L.

Abstract not provided.

Ruzic, Brandon R.; Revelle, Melissa R.; Maunz, Peter L.

Abstract not provided.

Revelle, Melissa R.; Maunz, Peter L.; Landahl, Andrew J.; Blain, Matthew G.; Clark, Susan M.; Lobser, Daniel L.; Muller, Richard P.; Rudinger, Kenneth M.; Yale, Christopher G.

Abstract not provided.

Maunz, Peter L.; Clark, Susan M.; Landahl, Andrew J.; Lobser, Daniel L.; Revelle, Melissa R.; Rudinger, Kenneth M.; Yale, Christopher G.

Abstract not provided.

Revelle, Melissa R.; Hogle, Craig W.; Ruzic, Brandon R.; Maunz, Peter L.; Young, Kevin C.; Lobser, Daniel L.

Abstract not provided.

Proctor, Timothy J.; Revelle, Melissa R.; Carignan-Dugas, Arnaud C.; Blume-Kohout, Robin J.; Lobser, Daniel L.; Maunz, Peter L.; Young, Kevin C.

Abstract not provided.

Rudinger, Kenneth M.; Kimmel, Shelby H.; Lobser, Daniel L.; Maunz, Peter L.

Abstract not provided.

Rudinger, Kenneth M.; Kimmel, Shelby H.; Lobser, Daniel L.; Maunz, Peter L.

Abstract not provided.

Maunz, Peter L.; Lobser, Daniel L.; Blume-Kohout, Robin J.; Fortier, Kevin M.; Mizrahi, Jonathan M.; Nielsen, Erik N.; Rudinger, Kenneth M.; Stick, Daniel L.; Blain, Matthew G.

Abstract not provided.

Lobser, Daniel L.; Blain, Matthew G.; Blume-Kohout, Robin J.; Fortier, Kevin M.; Mizrahi, Jonathan M.; Nielsen, Erik N.; Rudinger, Kenneth M.; Sterk, Jonathan D.; Stick, Daniel L.; Maunz, Peter L.

Abstract not provided.

Maunz, Peter L.; Blume-Kohout, Robin J.

Abstract not provided.

Lobser, Daniel L.; Blain, Matthew G.; Blume-Kohout, Robin J.; Fortier, Kevin M.; Mizrahi, Jonathan M.; Nielsen, Erik N.; Rudinger, Kenneth M.; Sterk, Jonathan D.; Stick, Daniel L.; Maunz, Peter L.

Abstract not provided.

Rudinger, Kenneth M.; Blume-Kohout, Robin J.; Nielsen, Erik N.; Gamble, John K.; Maunz, Peter L.; Young, Kevin C.; Lobser, Daniel L.

Abstract not provided.

Blume-Kohout, Robin J.; Gamble, John K.; Nielsen, Erik N.; Rudinger, Kenneth M.; Maunz, Peter L.; Lobser, Daniel L.; Fortier, Kevin M.; Silva, Marcus d.; Riste, Diego R.; Ware, Matt W.; Ryan, Colm A.

Abstract not provided.

Maunz, Peter L.; Blume-Kohout, Robin J.; Blain, Matthew G.; Benito, Francisco B.; Berry, Christopher W.; Clark, Craig R.; Clark, Susan M.; Colombo, Anthony P.; Dagel, Amber L.; Fortier, Kevin M.; Haltli, Raymond A.; Heller, Edwin J.; Lobser, Daniel L.; Mizrahi, Jonathan M.; Nielsen, Erik N.; Resnick, Paul J.; Rembetski, John F.; Rudinger, Kenneth M.; Scrymgeour, David S.; Sterk, Jonathan D.; Tabakov, Boyan T.; Tigges, Chris P.; Van Der Wall, Jay W.; Stick, Daniel L.

Abstract not provided.

Maunz, Peter L.; Sterk, Jonathan D.; Lobser, Daniel L.; Parekh, Ojas D.; Ryan-Anderson, Ciaran R.

In recent years, advanced network analytics have become increasingly important to na- tional security with applications ranging from cyber security to detection and disruption of ter- rorist networks. While classical computing solutions have received considerable investment, the development of quantum algorithms to address problems, such as data mining of attributed relational graphs, is a largely unexplored space. Recent theoretical work has shown that quan- tum algorithms for graph analysis can be more efficient than their classical counterparts. Here, we have implemented a trapped-ion-based two-qubit quantum information proces- sor to address these goals. Building on Sandia's microfabricated silicon surface ion traps, we have designed, realized and characterized a quantum information processor using the hyperfine qubits encoded in two 171 Yb + ions. We have implemented single qubit gates using resonant microwave radiation and have employed Gate set tomography (GST) to characterize the quan- tum process. For the first time, we were able to prove that the quantum process surpasses the fault tolerance thresholds of some quantum codes by demonstrating a diamond norm distance of less than 1 . 9 x 10 [?] 4 . We used Raman transitions in order to manipulate the trapped ions' motion and realize two-qubit gates. We characterized the implemented motion sensitive and insensitive single qubit processes and achieved a maximal process infidelity of 6 . 5 x 10 [?] 5 . We implemented the two-qubit gate proposed by Molmer and Sorensen and achieved a fidelity of more than 97 . 7%.