Integrated Photonics Research, Silicon and Nanophotonics (IPR)
Events
Integrated Photonics Research, Silicon and Nanophotonics (IPR)
28 July – 01 August 2024 | Québec City, Québec, Canada
The premier and longest-running meeting dedicated to groundbreaking advances in the research and development of integrated photonic and nano-photonic technologies on all relevant material platforms.
IPR brings together experts from both academia and industry for an open discussion of cutting-edge research, trends and problems.
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Integrated Photonics Research, Silicon and Nanophotonics (IPR)
Topics
Integrated Photonics Research (IPR)
- Photonic Devices
- Active and passive photonic integrated devices including lasers, modulators, detectors, isolators, amplifiers, switches, filters, and waveguides, fabricated from various materials including
- Compound semiconductors
- Silicon and other group IV semiconductors
- Dielectrics and polymers
- Lithium niobate and other Pockels effect based materials
- Silicon nitride
- Phase change materials
- Fabrication and characterization technologies for photonic integrated circuits and devices
- Lithography and etching techniques
- Micromachining techniques
- Growth and deposition approaches
- Self-organized fabrication methods
- Novel assembly and manufacturing techniques
- Heterogeneous and hybrid integration of materials and structures
- Foundry-based fabrication for mass production
- Linear and electro-optic waveguide characterization
- Micro- and nano-structure characterization
- Reliability advances and issues
- Packaging technologies and fiber-to-chip coupling
- Nano- and meta-photonic devices
- Topological photonics
- Photonic crystal devices including waveguides, resonators, and light sources
- Nano-engineered and sub-wavelength devices for light generation, waveguiding and detection
- Nanostructured photovoltaics
- Plasmonics
- Metasurfaces
- Device theory, modelling and design
- Modelling, design and optimization based on advanced approaches including machine learning and reverse engineering
- Novel device theories and physical insights
- Active and passive photonic integrated devices including lasers, modulators, detectors, isolators, amplifiers, switches, filters, and waveguides, fabricated from various materials including
- Applications of Photonic Integrated Circuits (PICs)
- PICs for classical applications including:
- Telecom and datacom
- Computing
- LiDAR and integrated optical phased arrays
- PICs for quantum computing and communication and for artificial intelligence
- Optical quantum memories and computing
- Optical quantum communication and key distribution
- On-chip optical trapping
- Optical neuromorphic computing
- Artificial intelligence, machine learning and edge computing
- PICs for precision timing and atomic physics
- Modelocked lasers and frequency combs
- Ultra-narrow linewidth oscillators
- Optical references
- Novel applications of PICs
- On-chip biochemical sensors and transducers
- New functionalities implemented in PICs
- PICs for classical applications including:
- Integrated Nonlinear and Quantum Optics
- On-chip nonlinear-optical pulse propagation and nonlinear-optical devices
- Solitons, supercontinuum generation, and frequency combs
- Nonlinear switching, modulation, memories and logic on-chip devices
- Nonlinear optics in devices based on novel materials including metamaterials, thin films, and 2D materials
- Nonlinear opto-mechanics
- On-chip nonlinear frequency conversion for classical and quantum applications
- Frequency comb generation
- Harmonic generation
- Raman and Brillouin gain
- Frequency (up/down) conversion
- Frequency conversion-based generation of single/entangled photons
- On-chip quantum sources and detectors
- Quantum dots and other single-photon sources
- Quantum state characterization including single photon detection and homo/heterodyne detection
- Quantum transduction approaches including microwave-optical bridging and hybridization
- Quantum opto-mechanics
- Squeezed states generation and detection
- On-chip nonlinear-optical pulse propagation and nonlinear-optical devices
- New Materials for Integrated Photonics
- Application driven advances
- Energy efficiency through materials advances
- Materials for optical computation
- New materials and integration approaches for active systems
- Heterogeneous and hybrid material platforms and integration
- Novel materials for quantum photonic devices and emitters
- New materials for nonlinear optical devices
- Extreme materials and interactions
- Beyond graphene: the new class of 2D materials for active and passive photonic devices
- Exceptional photonics: materials, devices and physics with exceptional points
- Epsilon near zero and near zero index materials
- Phase change materials for dynamic photonics
- Materials for spatio-temporal modulation and time crystals
- Biomimetic and bio-inspired materials
- Metamaterials
- Application driven advances
