Shaping caustics into propagation-invariant light
Zannotti Alessandro, Denz Cornelia, Alonso Miguel A.,Dennis Mark R.
Forschungsartikel (Zeitschrift) | Peer reviewedZusammenfassung
Structured light has revolutionized optical particle manipulation, nano-scaled material processing, and high-resolution imaging. In particular, propagation-invariant light fields such as Bessel, Airy, or Mathieu beams show high robustness and have a self-healing nature. To generalize such beneficial features, these light fields can be understood in terms of caustics. However, only simple caustics have found applications in material processing, optical trapping, or cell microscopy. Thus, these technologies would greatly benefit from methods to engineer arbitrary intensity shapes well beyond the standard families of caustics. We introduce a general approach to arbitrarily shape propagation-invariant beams by smart beam design based on caustics. We develop two complementary methods, and demonstrate various propagation-invariant beams experimentally, ranging from simple geometric shapes to complex image configurations such as words. Our approach generalizes caustic light from the currently known small subset to a complete set of tailored propagation-invariant caustics with intensities concentrated around any desired curve
Details zur Publikation
Autor*innen der Universität Münster
| Denz, Cornelia | Professur für Angewandte Physik (Prof. Denz) |
| Zannotti, Alessandro | Professur für Angewandte Physik (Prof. Denz) |
Preisverleihungen erhalten für die Publikation
| Customizing Caustics (Aufnahme in die weltweite Liste der 30 besten Veröffentlichungen des Jahres 2020 aus den Bereichen Optik und Photonik) Verliehen von: Optical Society of America; Journal "Optics and Photonics News" Verliehen an: Zannotti, Alessandro; Alonso, Miguel A.; Dennis Marc R; Denz, Cornelia. Bekannt gegeben am: 15.12.2020 | Verleihung erfolgte am: 15.12.2020 Art der Preisverleihung: Preis für beste Veröffentlichung |