What Is Photonics?

By Owais AliReviewed by Lexie CornerOct 2 2024

This article provides an overview of photonics, covering its fundamental principles, key technologies, applications, and emerging trends.

Image Credit: luchschenF/Shutterstock.com

Fundamentals of Photonics

Photonics is the study of light and other forms of radiant energy. It involves generating, manipulating, and detecting light using optical components, lasers, fiber optics, and electro-optical instruments. It covers processes such as emission, transmission, deflection, and amplification.

The applications of photonics are extensive, ranging from energy generation and detection to telecommunications and information processing. It has significantly impacted various fields, including communication, healthcare, navigation, and astronomy, establishing itself as a vital component of modern technology and scientific understanding.

Historical Background

The term "photonics," introduced by French physicist Pierre Aigrain in the 1960s, gained recognition in the 1980s through publications from institutions like Bell Laboratories and Hughes Aircraft Co.

Initially, photonics focused on applying light to tasks traditionally handled by electronics. However, with the invention of the laser, photonics rapidly advanced, leading to innovations such as optical fibers, laser diodes, and integrated photonic circuits.

These developments have enabled high-speed data transmission, enhanced medical procedures, and improved manufacturing processes, showcasing the broad impact of photonics across various industries.^1,2

Key Technologies in Photonics

Photonics encompasses a wide range of tools and techniques centered around manipulating light. Some of the most essential technologies include:

Imaging

Photonic imaging technologies capture and process environmental information, spanning applications from smartphone photography to advanced medical procedures like optical coherence tomography for microsurgery. This field covers various imaging techniques, such as multispectral, thermal, hyperspectral, photoacoustic, gravitational, and speckle imaging.

Lasers

Lasers generate highly concentrated beams of light, enabling applications such as LiDAR, digital projection, and barcode scanning. Their versatility spans from large-scale synchrotrons to tiny vertical-cavity surface-emitting lasers (VCSELs), each tailored for specific tasks, including industrial cutting and medical procedures.

Sensors

Sensors convert light into electrical signals, facilitating the detection and measurement of light in applications ranging from cameras to medical diagnostics and environmental sensors.

Lenses and Microscopy

Lenses manipulate light through refraction, facilitating magnification and aberration correction functions. Their effectiveness is influenced by their shape and materials, such as plastics, quartz glass, and borosilicate glass, each possessing distinct properties suited for various wavelengths and operational conditions.

Microscopy uses optical techniques, such as fluorescence microscopy and super-resolution microscopy, to observe tiny objects and phenomena. Super-resolution microscopy surpasses the diffraction limit, allowing visualization of structures at the nanoscale.

Optical fibers

Optical fibers are thin strands of glass or plastic that facilitate high-speed data transmission, particularly in fiber optic communication. They provide significant advantages over traditional electrical cables, including longer distances and higher bandwidths, and find applications in illumination, imaging, and sensing technologies.

Spectroscopy

Spectroscopy analyzes the interaction of light with matter to identify materials and their properties. It finds applications in chemistry, biology, and environmental monitoring, enabling precise substance identification based on spectral signatures.³

Applications of Photonics

High-Speed Connectivity

Fiber optic networks have revolutionized global communications, enabling high-speed internet and supporting the infrastructure of our digital world. A single optical fiber can simultaneously carry millions of phone calls, significantly improving connectivity and internet speeds.

Recent advancements in terahertz photonics are expected to enhance 5G technology by utilizing millimeter frequencies, which could enhance high-speed connections and reduce electromagnetic spectrum congestion.⁴

Healthcare

In biology and medicine, photonic technologies enable minimally invasive surgeries, early disease detection, and advanced imaging techniques. For example, optical coherence tomography (OCT) enables the early detection of diseases such as Alzheimer's and glaucoma.

Biophotonics, which employs light-based technologies in biomedical sciences, plays a crucial role in analyzing molecular processes, enhancing the understanding of disease origins, and supporting the development of preventive measures and new treatments.

Smart Agriculture Solutions

Hyperspectral imaging, spectroscopy, and machine vision enhance automated agricultural sorting, inspection, and testing. These techniques improve farming efficiency and food safety, while light management supports hydroponic greenhouses, enabling food production in challenging climates.

Automated Manufacturing

Photonics has transformed manufacturing by advancing automation through improved imaging and computation technologies, allowing robots to handle complex tasks like bin picking. The increasing use of lasers for precision cutting and welding has boosted production efficiency, supporting high-volume, cost-effective operations while enabling mass customization and promoting resource-efficient manufacturing processes.⁵

Clean Energy

Photonics plays a crucial role in clean energy by enabling photovoltaic cells in solar panels to convert sunlight into sustainable electricity. Advances in materials like quantum dots and perovskite have notably improved solar efficiency.

For example, LONGi recently achieved a world record of 30.1 % efficiency for commercial M6-size wafer-level silicon-perovskite tandem solar cells. These developments enhance energy production and support global efforts toward sustainable energy solutions.^6,7

Emerging applications

Metasurfaces

Metasurfaces have gained prominence in photonics due to their ability to create flat, compact optical components with customizable properties. They manipulate light properties such as phase, amplitude, and polarization through nanoscale geometric configurations.

Recently, researchers at Arizona State University developed a scalable manufacturing technique for functional metasurfaces, enabling rapid, efficient, and cost-effective production. This approach supports the transition from research to commercial applications in various industries, including microelectronics and information processing.^8,9

Quantum Photonics

The integration of photonics and quantum mechanics has led to the development of quantum photonics, which harnesses the quantum properties of light to advance photonic technology beyond traditional limits. Quantum sensors, for instance, utilize the high sensitivity of quantum states for applications in medicine, defense, and communications, allowing for atomic-scale imaging and gravitational wave detection.

In computing, Google's 54-qubit Sycamore quantum processor exemplifies this potential by completing a task in 200 seconds that would require supercomputers 10,000 years, highlighting the transformative impact of quantum photonics on modern technology.¹⁰

Silicon Photonics

Silicon photonics has become increasingly important due to the growing demand for high-speed data transmission in data centers and the rollout of 5G technology. Silicon optical transceivers facilitate interconnections within data centers, with anticipated future developments focusing on intra-chip communications.

A study published in Nature Electronics introduced a high-performance silicon photonic transmitter, achieving speeds of 112 gigabaud and 224 gigabits per second while maintaining energy consumption below picojoules per bit. This CMOS-compatible design represents a cost-effective advancement in high-speed communication technologies.¹¹

Machine Vision and AI

The integration of machine vision with AI is transforming automation across industries, enhancing the efficiency of manufacturing and assembly processes. This convergence enables real-time monitoring and analysis, allowing for rapid decision-making and significant reductions in operational costs.

For instance, the Tsinghua University researchers developed an optical parallel computational array (OPCA) photonic chip that processes images in nanoseconds. This chip integrates AI-driven analysis directly into optical processing, bypassing the need for optical-to-electronic conversions and enabling faster image processing for edge intelligence applications like autonomous driving and industrial inspection.¹²

Plasmonics

Plasmonics is a subfield that explores the interaction between electromagnetic fields and electrons in metals, enabling the localization of light beyond the diffraction limit. Recent advancements in plasmonic nanomaterials through techniques like "shadow growth" allow for the creation of nanoscale structures with tunable optical properties, with potential applications in nanorobots for drug delivery, photonic devices, and chiral spectroscopy.¹³

Conclusion

Photonics has become indispensable to our technological landscape, driving innovations in communication, healthcare, and clean energy. The integration of quantum technology and artificial intelligence promises to enhance the efficiency and effectiveness of systems across various sectors, leading to groundbreaking advancements that will reshape industries and improve quality of life.

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References and Further Reading

1. Amiri, IS., Azzuhri, SRB., Jalil, MA., Hairi, HM., Ali, J., Bunruangses, M., Yupapin, P. (2018). Introduction to Photonics: Principles and the Most Recent Applications of Microstructures. Micromachines. https://doi.org/10.3390/mi9090452
2. Castellani, CES., Silva, LC., Segatto, MEV. (2024). The Rise of Photonics Engineering. [Online] Federal University of Esp´ırito Santo. Electrical Engineering Department. Available at: https://www.sbmo.org.br/documentos_sistema/95a000f17f6e0c67db9ce4d30ddbf6f4.pdf
3. Photonics Media. (2024). What Is Photonics? [Online] Photonics. Available at: https://www.photonics.com/Articles/What_Is_Photonics/a65926
4. Violino, B. (2022). Photonics: A key component of Industry 4.0. [Online] LaserFocusWorld. Available at: https://www.laserfocusworld.com/lasers-sources/article/14233619/photonics-a-key-component-of-industry-40
5. Amsalu, K., Palani, S. (2019). A review on photonics and its applications. Materials Today: Proceedings. https://doi.org/10.1016/j.matpr.2020.05.184
6. LONGI. (2024). LONGi announces the new world record efficiency of 30.1% for the commercial M6 size wafer-level silicon-perovskite tandem solar cells. [Online] LONGI. Available at: https://www.longi.com/en/news/is-m6-wafer-silicon-perovskite-tandem-cells-new-efficiency-record/
7. European Commission. (2022). Photonics. [Online] European Commission. Available at: https://digital-strategy.ec.europa.eu/en/policies/photonics
8. Schulz, SA., et al. (2024). Roadmap on photonic metasurfaces. Applied Physics Letters. https://doi.org/10.1063/5.0204694
9. Choi, S., Zuo, J., Das, N., Yao, Y., Wang, C. Scalable Nanoimprint Manufacturing of Functional Multilayer Metasurface Devices. Advanced Functional Materials. https://doi.org/10.1002/adfm.202404852
10. Rincon, P. (2019). Google claims 'quantum supremacy' for computer. [Online] BBC. Available at: https://www.bbc.com/news/science-environment-50154993
11. Li, K., Thomson, DJ., Liu, S., Zhang, W., Cao, W., Littlejohns, CG., Yan, X., Ebert, M., Banakar, M., Tran, D., Meng, F., Du, H., Reed, G. T. (2023). An integrated CMOS–silicon photonics transmitter with a 112 gigabaud transmission and picojoule per bit energy efficiency. Nature Electronics. https://doi.org/10.1038/s41928-023-01048-1
12. Wu, W., Zhou, T., Fang, L. (2024). Parallel photonic chip for nanosecond end-to-end image processing, transmission, and reconstruction. Optica. https://doi.org/10.1364/OPTICA.516241
13. Han, H., Kim, D., Kim, J., Kim, G., Fischer, P., Jeong, H. (2023). Plasmonic Nanostructure Engineering with Shadow Growth. Advanced Materials. https://doi.org/10.1002/adma.202107917

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