David S. Barth scite author profile

David S. Barth

4Publications

71Citation Statements Received

81Citation Statements Given

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148

Affiliations

Center for Nanoscale Science and Technology, University of California, Berkeley

Publications

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Asymmetric Free-Space Light Transport at Nonlinear Metasurfaces

et al. 2018

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Asymmetric light transport has significantly contributed to fundamental science and revolutionized advanced technology in various aspects such as unidirectional photonic devices, optical diodes and isolators. While metasurfaces mold wavefronts at will with an ultrathin flat optical element, asymmetric transport of light cannot be fundamentally achieved by any linear system including linear metasurfaces. We report asymmetric transport of free-space light at nonlinear metasurfaces upon transmission and reflection. Moreover, we theoretically derived the nonlinear generalized Snell's laws that were experimentally confirmed by the anomalous nonlinear refraction and reflection. The asymmetric transport at optically thin nonlinear interfaces is revealed by the concept of reversed propagation path. Such an asymmetric transport at metasurfaces opens a new paradigm for free-space ultrathin lightweight optical devices with one-way operation including unrivaled optical valves and diodes.

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Dissipative self-organization in optical space

et al. 2018

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Macroscale Transformation Optics Enabled by Photoelectrochemical Etching

et al. 2015

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Tunable thermal conductivity in mesoporous silicon by slight porosity change

Seol

Barth

Zhu

et al. 2017

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We report the thermal conductivity of photoelectrochemically synthesized mesoporous silicon (MPS), with ∼20-nm diameter pores and 52%–58% porosity. The thermal conductivity of MPS samples with a thickness of a few microns was measured using the three omega (3ω) differential technique. We experimentally demonstrated that the thermal conductivity of MPS varies between 3 and 7 W/m K at room temperature and is dependent on the photoelectrochemical etching times used during the MPS synthesis, which induces a slight change in the MPS porosity. Calculations were conducted using the Boltzmann transport equation in the relaxation time approximation, with the results suggesting that the large thermal conductivity reduction in the MPSs was not entirely explained by the pore boundary scattering. Our findings indicate that elastic softening in the mesoporous structure may be responsible for the reduction in the thermal conductivity.

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David S. Barth

Asymmetric Free-Space Light Transport at Nonlinear Metasurfaces

Dissipative self-organization in optical space

Macroscale Transformation Optics Enabled by Photoelectrochemical Etching

Tunable thermal conductivity in mesoporous silicon by slight porosity change

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