Two‐Photon Laser Writing of Soft Responsive Polymers via Temperature‐Controlled Polymerization

Bellis, Isabella De; Nocentini, Sara; Santi, Maria Giulia Delli; Martella, Daniele; Parmeggiani, Camilla; Zanotto, Simone; Wiersma, Diederik S.

doi:10.1002/lpor.202100090

Cited by 13 publications

(12 citation statements)

References 66 publications

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“…Additionally, there exists minor reflection asymmetries between the crosspolarization reflection magnitudes r LR and r RL which might result from the fabricated chiral metasurfaces without any rotational symmetry due to fabrication errors and accumulated measurement errors, resulting in the all elements in the Jones matrix are different. [57] Due to the scaling properties of Maxwell's equations and 3D printing techniques, therefore, this paradigm can be easily extended to other frequency ranges(Figure S10, Supporting Information) and fabricated by integrating various 3D printing techniques with appropriate printing resolution and printing scale, such as micro/nano scale two-photon polymerization (TPP) based 3D printing techniques [58][59][60] for optical metasurfaces, millimeter-scale projection stereolithography-based 3D printing techniques [61] and fused deposition modeling (FDM) printing techniques [62] for microwave metasurfaces. Such strong chiroptical responses together with the concise and general design principle, and the simple, scalable, low-cost, and lithographyfree fabrication strategy, hold promising potential in various chirality-related applications, such as chiral sensing, imaging, spectroscopy, and polarimetry.…”

Section: Resultsmentioning

confidence: 99%

Chiral Metasurfaces with Maximum Circular Dichroism Enabled by Out‐of‐Plane Plasmonic System

Shen

Fan

Yin

et al. 2022

Laser & Photonics Reviews

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Chiral metasurfaces with pronounced reflective chiroptical responses have drawn extensive attention as they can offer great opportunities for various chirality-related applications. However, their fascinating potential are restrained by limited chiroptical responses, relatively complex design principle, and fabrication strategy. Herein, a concise and general design principle to develop out-of-plane reflective chiral metasurfaces, empowered with the maximum theoretical circular dichroism (CD), is theoretically proposed and experimentally demonstrated. The designed out-of-plane chiral metasurfaces operating in the terahertz (THz) region are flexibly fabricated via a simple, scalable, low-cost and lithography-free fabrication strategy by integrating a three-dimensional (3D) printing technique. Finally, the methodological stabilities and the strong chiroptical responses of proposed chiral metasurfaces are validated experimentally. From the general design principle, simple fabrication strategy as well as maximum chiroptical responses of proposed reflective chiral metasurfaces, it can be envisaged that these findings may overcome the difficulties in design, optimization, and fabrication for reflective chiral metasurfaces and provide promising potentials for various chirality-related applications in emerging THz technologies, such as chiral sensing, imaging, spectroscopy and polarimetry.

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Section: Resultsmentioning

confidence: 99%

Chiral Metasurfaces with Maximum Circular Dichroism Enabled by Out‐of‐Plane Plasmonic System

Shen

Fan

Yin

et al. 2022

Laser & Photonics Reviews

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“…One major hurdle in the fabrication of soft photonic structures is the reproducibility of the results and the fidelity of the final structure with respect to the intended design, which was here overcome by the temperature‐controlled TP‐DLW [ 42 ] also leading to a more spheroidal shape of the voxel. Figure 3b,c shows two PCs printed at room temperature and 10 °C, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…As expected, the treatment [ 46 ] determines a slight blueshift due to the overall reduction of the rod minor and major axis. [ 42 ] Moreover, thanks to the swelling decrease, the periodicity of the structure is improved (see Figure 2d–f), therefore producing a larger attenuation (10% reduction) of the woodpile transmission at the stop band. One major difference in the 3D printing of soft materials at different temperatures is the reproducibility of the process.…”

Section: Resultsmentioning

confidence: 99%

“…The authors have already shown that a polymerization temperature of 10 °C slows down the monomer diffusion in soft responsive materials, improving the resolution and the mechanical stability up to performances typical of commercial glassy resists. [ 42 ] Furthermore, lowering the polymerization temperature makes the polymerizable unit (the voxel) more spheroidal thus reducing the aspect ratio (i.e., the ratio among the major and minor axis of the voxel) and, last but not least, greatly improves the reproducibility of the printed structures, thus opening to the fabrication of photonic crystals able to work in dry environment.…”

Section: Introductionmentioning

confidence: 99%

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Temperature Tunable 4D Polymeric Photonic Crystals

Bellis¹,

Martella

Parmeggiani

et al. 2023

Adv Funct Materials

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Photonic crystals owe their multitude of optical properties to the way their structure creates interference effects. It is therefore possible to influence the photonic response by acting on their physical structure. In this article, tunable photonic crystals made by elastic polymers that respond to their environment are explored, in particular with a physical deformation under temperature variation. This creates a feedback process in which the photonic response depends on its physical structure, which itself is influenced by the environmental changes. By using a multi‐photon polymerization process specifically optimized for soft responsive polymers such as Liquid Crystalline Networks, highly resolved, reproducible, and mechanically self‐standing photonic crystals are fabricated. The physical structure of the 3D woodpile can be tuned by an external temperature variation creating a reversible spectral tuning of 50 nm in the telecom wavelength range. By comparing these results with finite element calculations and temperature induced shape‐change, it is confirmed that the observed tuning is due to an elastic deformation of the structure. The achieved nanometric patterning of tunable anisotropic photonic materials will further foster the development of reconfigurable photonic crystals with point defects acting as tunable resonant cavities and, more in general, of 4D nanostructures.

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“…Multi‐photon 3D laser micro‐ and nanoprinting of polymers [ 1,2 ] has become a commercially available and routine research tool in optics, [ 3–5 ] mechanics, [ 6–8 ] biology, [ 9,10 ] and micro‐robotics, [ 11–15 ] and is starting to enter the industrial market. Even multi‐material multi‐photon 3D printing is emerging.…”

Section: Introductionmentioning

confidence: 99%

In Situ Diagnostics and Role of Light‐Induced Forces in Metal Laser Nanoprinting

Yang

Rahimzadegan

Hahn

et al. 2022

Laser & Photonics Reviews

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Compared to 3D laser nanoprinting of polymers, the mechanisms in laser nanoprinting of metals are rather poorly understood. For the example of platinum investigated here, the printing process starts with the formation of metal nanoparticles by photo‐reduction of metal salts in aqueous solution in a diffraction‐limited laser focus. To investigate the printing process in situ, a weak continuous‐wave probe laser is co‐focused in addition to the focused femtosecond printing laser. The light of the probe laser is backscattered off the emerging metal structures, and recorded with a temporal resolution of 1 µs. It is found that the formed metal nanoparticles are quickly ejected from the focus on a timescale of some 10 µs. Once a nanoparticle randomly adheres to the substrate surface, it serves as a seed from which structures can be built‐up. The following nanoparticles are sintered onto that seed to form a metallic voxel on a timescale of some 10 ms. By polarization‐dependent experiments and full‐wave optical simulations, it is shown that light‐induced forces onto the nanoparticles play a significant role. The improved understanding of the microscopic processes in metal nanoprinting is a prerequisite for further process optimizations and applications, for example in terms of printed optoelectronics.

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Two‐Photon Laser Writing of Soft Responsive Polymers via Temperature‐Controlled Polymerization

Cited by 13 publications

References 66 publications

Chiral Metasurfaces with Maximum Circular Dichroism Enabled by Out‐of‐Plane Plasmonic System

Chiral Metasurfaces with Maximum Circular Dichroism Enabled by Out‐of‐Plane Plasmonic System

Temperature Tunable 4D Polymeric Photonic Crystals

In Situ Diagnostics and Role of Light‐Induced Forces in Metal Laser Nanoprinting

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