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1. Excitation Dependence in Photoiniferter Polymerization

   https://doi.org/10.1021/acsmacrolett.2c00683  

   Hughes, Rhys W.; Lott, Megan E.; Bowman, Jared I.; Sumerlin, Brent S. (January 2023, ACS Macro Letters)
2. Impulsive wave excitation by rapidly changing granules

   https://doi.org/10.1051/0004-6361/202038288  

   Kwak, Hannah; Chae, Jongchul; Madjarska, Maria S.; Cho, Kyuhyoun; Song, Donguk (October 2020, Astronomy & Astrophysics)

   It is not yet fully understood how magnetohydrodynamic waves in the interior and atmosphere of the Sun are excited. Traditionally, turbulent convection in the interior is considered to be the source of wave excitation in the quiet Sun. Over the last few decades, acoustic events observed in the intergranular lanes in the photosphere have emerged as a strong candidate for a wave excitation source. Here we report our observations of wave excitation by a new type of event: rapidly changing granules. Our observations were carried out with the Fast Imaging Solar Spectrograph in the H α and Ca  II 8542 Å lines and the TiO 7057 Å broadband filter imager of the 1.6 m Goode Solar Telescope at the Big Bear Solar Observatory. We identify granules in the internetwork region that undergo rapid dynamic changes such as collapse (event 1), fragmentation (event 2), or submergence (event 3). In the photospheric images, these granules become significantly darker than neighboring granules. Following the granules’ rapid changes, transient oscillations are detected in the photospheric and chromospheric layers. In the case of event 1, the dominant period of the oscillations is close to 4.2 min in the photosphere and 3.8 min in the chromosphere. Moreover, in the Ca  II –0.5 Å raster image, we observe repetitive brightenings in the location of the rapidly changing granules that are considered the manifestation of shock waves. Based on our results, we suggest that dynamic changes of granules can generate upward-propagating acoustic waves in the quiet Sun that ultimately develop into shocks. 

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3. Excitation of Nonradiating Anapoles in Dielectric Nanospheres

   https://doi.org/10.1103/PhysRevLett.124.097402  

   Parker, John A.; Sugimoto, Hiroshi; Coe, Brighton; Eggena, Daniel; Fujii, Minoru; Scherer, Norbert F.; Gray, Stephen K.; Manna, Uttam (March 2020, Physical Review Letters)
4. Parametric Excitation of a Repulsive Force Actuator

   https://doi.org/10.1115/DETC2017-67381  

   Pallay, Mark; Towfighian, Shahrzad (August 2017, ASME International Design Engineering Technical Conferences)

   Parametric resonances in a repulsive-force MEMS resonator are investigated. The repulsive force is generated through electrostatic fringe fields that arise from a specific electrode configuration. Because of the nature of the electrostatic force, parametric resonance occurs in this system and is predicted using Mathieu’s Equation. Governing equations of motion are solved using numerical shooting techniques and show both parametric and subharmonic resonance at twice the natural frequency. The primary instability tongue for parametric resonance is also mapped. This is of particular interest for MEMS sensors that require high signal-to-noise ratios due to the large oscillation amplitudes associated with parametric resonance. 

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5. Carrier-Envelope Phase-Dependent Strong-Field Excitation

   https://doi.org/10.1103/PhysRevLett.128.173201  

   Chetty, D.; Glover, R. D.; Tong, X. M.; deHarak, B. A.; Xu, H.; Haram, N.; Bartschat, K.; Palmer, A. J.; Luiten, A. N.; Light, P. S.; et al (April 2022, Physical Review Letters)