Publications

Reinke, Charles M.; Siddiqui, Aleem M.; Shin, Heedeuk S.; Jarecki, Robert L.; Starbuck, Andrew L.; Rakich, Peter T.

Abstract not provided.

Proceedings of SPIE - The International Society for Optical Engineering

Siddiqui, Aleem M.; Reinke, Charles M.; Shin, Heedeuk; Jarecki, Robert L.; Starbuck, Andrew L.; Rakich, Peter

The performance of electronic systems for radio-frequency (RF) spectrum analysis is critical for agile radar and communications systems, ISR (intelligence, surveillance, and reconnaissance) operations in challenging electromagnetic (EM) environments, and EM-environment situational awareness. While considerable progress has been made in size, weight, and power (SWaP) and performance metrics in conventional RF technology platforms, fundamental limits make continued improvements increasingly difficult. Alternatively, we propose employing cascaded transduction processes in a chip-scale nano-optomechanical system (NOMS) to achieve a spectral sensor with exceptional signal-linearity, high dynamic range, narrow spectral resolution and ultra-fast sweep times. By leveraging the optimal capabilities of photons and phonons, the system we pursue in this work has performance metrics scalable well beyond the fundamental limitations inherent to all electronic systems. In our device architecture, information processing is performed on wide-bandwidth RF-modulated optical signals by photon-mediated phononic transduction of the modulation to the acoustical-domain for narrow-band filtering, and then back to the optical-domain by phonon-mediated phase modulation (the reverse process). Here, we rely on photonics to efficiently distribute signals for parallel processing, and on phononics for effective and flexible RF-frequency manipulation. This technology is used to create RF-filters that are insensitive to the optical wavelength, with wide center frequency bandwidth selectivity (1-100GHz), ultra-narrow filter bandwidth (1-100MHz), and high dynamic range (70dB), which we will present. Additionally, using this filter as a building block, we will discuss current results and progress toward demonstrating a multichannel-filter with a bandwidth of < 10MHz per channel, while minimizing cumulative optical/acoustic/optical transduced insertion-loss to ideally < 10dB. These proposed metric represent significant improvements over RF-platforms.

AIP Advances

Reinke, Charles M.; El-Kady, I.

We present a scalable phonon-based quantum computer on a phononic crystal platform. Practical schemes involve selective placement of a single acceptor atom in the peak of the strain field in a high-Q phononic crystal cavity that enables coupling of the phonon modes to the energy levels of the atom. We show theoretical optimization of the cavity design and coupling waveguide, along with estimated performance figures of the coupled system. A qubit can be created by entangling a phonon at the resonance frequency of the cavity with the atom states. Qubits based on this half-sound, half-matter quasi-particle, called a phoniton, may outcompete other quantum architectures in terms of combined emission rate, coherence lifetime, and fabrication demands.

Applied Physics Letters

Ghasemi Baboly, M.; Raza, A.; Brady, J.; Reinke, Charles M.; Leseman, Z.C.; El-Kady, I.

The systematic design, fabrication, and characterization of an isolated, single-mode, 90° bend phononic crystal (PnC) waveguide are presented. A PnC consisting of a 2D square array of circular air holes in an aluminum substrate is used, and waveguides are created by introducing a line defect in the PnC lattice. A high transmission coefficient is observed (-1 dB) for the straight sections of the waveguide, and an overall 2.3 dB transmission loss is observed (a transmission coefficient of 76%) for the 90° bend. Further optimization of the structure may yield higher transmission efficiencies. This manuscript shows the complete design process for an engineered 90° bend PnC waveguide from inception to experimental demonstration.

Reinke, Charles M.; Jarecki, Robert L.; Starbuck, Andrew L.; Shin, Heedeuk S.; Cox, Jonathan A.; Siddiqui, Aleem M.; Rakich, Peter T.

Abstract not provided.

Reinke, Charles M.

Abstract not provided.

El-Kady, I.; Reinke, Charles M.; Katzenmeyer, Aaron M.; Swartzentruber, Brian S.; Nielsen, Erik N.; Hill, Thomas A.

Abstract not provided.

Reinke, Charles M.; alaie, Seyedhamidreza a.; Goettler, Drew F.; Su, Mehmet F.; Leseman, Zayd C.; El-Kady, I.

Abstract not provided.

Rakich, Peter T.; Shin, Heedeuk S.; Reinke, Charles M.; Cox, Jonathan A.; Siddiqui, Aleem M.; Wang, Zheng W.; Hossein, Mousavi H.; Potter, Robert P.; Freeman, Rich F.; Behunin, Ryan O.; Kittlaus, Eric A.; Jarecki, Robert L.; Chu, Patrick B.

Abstract not provided.

El-Kady, I.; Reinke, Charles M.; Clark, Susan M.; Olsson, Roy H.; Bielejec, Edward S.

Abstract not provided.

El-Kady, I.; Reinke, Charles M.; Leseman, Zayd C.

Abstract not provided.

Siddiqui, Aleem M.; Cox, Jonathan A.; Reinke, Charles M.; Shin, Heedeuk S.; Rakich, Peter T.

Abstract not provided.

Clark, Susan M.; Fortier, Kevin M.; El-Kady, I.; McGuinness, Hayden J.; Stick, Daniel L.; Reinke, Charles M.

The Frequency Translation to Demonstrate a Hybrid Quantum Architecture project focused on developing nonlinear optics to couple two different ion species and make their emitted UV photons indistinguishable. Successful demonstration of photonic coupling of different ion species lays the foundation for coupling drastically different types of qubits, such as ions and quantum dots. Frequency conversion of single photons emitted from single ions remains a "hot" topic with many groups pursing this effort; however due to challenges in producing short period periodically poled crystal it has yet to be realized. This report details the efforts of trying to frequency convert single photons emitted from trapped ions to other wavelengths. We present our theoretical studies of candidate platforms for frequency conversion: photonic crystal fibers, X⁽²⁾ nonlinear crystals in optical cavities, and photonic crystal cavities. We also present experiment results in ion trapping X⁽²⁾ nonlinear crystals measurements and photonic crystal fabrication

Reinke, Charles M.; alaie, Seyedhamidreza a.; Su, Mehmet F.; Leseman, Zayd C.; El-Kady, I.

Abstract not provided.

Reinke, Charles M.; alaie, Seyedhamidreza a.; Goettler, Drew, G.; Su, Mehmet F.; Leseman, Zayd C.; El-Kady, I.

Abstract not provided.

Rakich, Peter T.; Shin, Heedeuk S.; Reinke, Charles M.; Cox, Jonathan A.; Siddiqui, Aleem M.; Wang, Zheng W.; Hossein, Mousavi H.; Potter, Robert P.; Freeman, Rich F.; Behunin, Ryan O.; Jarecki, Robert L.; Wendt, J.R.; Chu, Patrick B.

Abstract not provided.

Reinke, Charles M.

Abstract not provided.

Nature Nanotechnology

El-Kady, I.; Reinke, Charles M.

Abstract not provided.

Eichenfield, Matthew S.; Givler, R.C.; Pfeifer, Kent B.; Reinke, Charles M.; Robinson, Alex L.; Resnick, Paul J.; Griffin, Benjamin G.; Langlois, Eric L.; Nielson, Gregory N.; Okandan, Murat O.

After years in the field, many materials suffer degradation, off-gassing, and chemical changes causing build-up of measurable chemical atmospheres. Stand-alone embedded chemical sensors are typically limited in specificity, require electrical lines, and/or calibration drift makes data reliability questionable. Along with size, these "Achilles' heels" have prevented incorporation of gas sensing into sealed, hazardous locations which would highly benefit from in-situ analysis. We report on development of an all-optical, mid-IR, fiber-optic based MEMS Photoacoustic Spectroscopy solution to address these limitations. Concurrent modeling and computational simulation are used to guide hardware design and implementation.

Kim, Jin K.; Leonhardt, Darin L.; Davids, Paul D.; Wendt, J.R.; Reinke, Charles M.; Montoya, John A.

Abstract not provided.

Reinke, Charles M.; El-Kady, I.

Abstract not provided.

Cox, Jonathan A.; Jarecki, Robert L.; Reinke, Charles M.; Camacho, Ryan C.; Davids, Paul D.

Abstract not provided.

Reinke, Charles M.; Olsson, Roy H.; El-Kady, I.

Abstract not provided.

El-Kady, I.; Reinke, Charles M.; Olsson, Roy H.; Bielejec, Edward S.

Abstract not provided.

Leonhardt, Darin L.; Kim, Jin K.; Reinke, Charles M.; Davids, Paul D.; Wendt, J.R.; Klem, John F.

Abstract not provided.