Michael Martin scite author profile

We present an optical characterization of photonic glasses, composed of randomly arranged, monodisperse dielectric spheres packed at high filling fractions. We provide a detailed optical study of the resonant behavior of diffuse light transport through such systems. By means of independent static and dynamic measurements, we show resonances in the transport mean free path, diffusion constant, and also energy velocity of light. We also show that the main transport parameters can be controlled by varying the sphere diameter.

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Who gets the benefits? An approach for assessing the environmental performance of industrial symbiosis

Martin

Svensson

Eklund

2015

Journal of Cleaner Production

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Industrial symbiosis networks are generally assumed to provide economic and environmental benefits for all firms involved, though few quantifications have been produced in the literature, and the methods for these quantifications have varied. This paper provides an approach to quantify environmental performance of industrial symbiosis using guidance from the literature of life cycle assessment. Additionally, an approach to distribute credits due to exchanges for firms in the industrial symbiosis network is outlined. From the approach, influential methodological considerations used for the quantifications are discussed, including e.g. the production of reference systems, allocation methods, system boundaries and functional unit. The implications of such an approach may be beneficial for the industrial symbiosis community and provide information crucial for taxes, subsidies, business relations, expansion possibilities for the network, marketing and other issues related to the environmental performance of firms in the industrial symbiosis network.

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Optical anisotropy and pinning of the linear polarization of light in semiconductor microcavities

Kłopotowski

Martin

Amo

et al. 2006

Solid State Communications

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We report a strong experimental evidence of the optical anisotropy in a CdTe-based microcavity: the polarization of light is pinned to one of the crystallographic axes independently on the polarization of the excitation. The polarization degree depends strongly on the excitation power, reaching almost 100 % in the stimulated regime. The relaxation time of the polarization is about 1 ns. We argue that all this is an effect of a splitting of the polariton doublet at k=0. We consider different sources for the splitting and conclude that the most likely one is optical birefringence in the mirrors and/or the cavity.

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Michael Martin

Circularity for circularity's sake? Scoping review of assessment methods for environmental performance in the circular economy.

Improving the environmental performance of biofuels with industrial symbiosis

Resonant light transport through Mie modes in photonic glasses

Who gets the benefits? An approach for assessing the environmental performance of industrial symbiosis

Optical anisotropy and pinning of the linear polarization of light in semiconductor microcavities

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