How to distinguish elastically scattered light from Stokes shifted light for solid-state lighting?

Meretska, Maryna L.; Lagendijk, Ad; Thyrrestrup, Henri; Mosk, Allard; IJzerman, Wilbert L.; Vos, Willem L.

doi:10.1063/1.4941688

Cited by 7 publications

(13 citation statements)

References 42 publications

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“…The absorption cross section tends to zero at the edges of the absorption spectral range (λ i =420 nm and 520 nm) in agreement with Ref. [45].…”

Section: Diffuse Light Transmission and Reflectionsupporting

confidence: 68%

“…The transmission and the reflection spectra reveal a deep trough with a minimum at λ i = 458 nm. The trough matches with the peak of the absorption band of YAG:Ce 3+ [45]. The presence of the trough indicates that a significant fraction of the light in this wavelength range is absorbed by the phosphor.…”

Section: Diffuse Light Transmission and Reflectionmentioning

confidence: 89%

“…The absorption spectrum of the phosphor particles has a peak absorption wavelength λ = 458 nm, and a broad linewidth (full width half maximum, FWHM) of ∆λ a = 55 nm, as reported earlier in Ref. [45]. Based on the absorption spectrum we choose the wavelength λ c = 520 nm to distinguish the absorbing range (λ = 400 nm to 520 nm) from the non-absorbing range (λ = 520 nm to 700 nm).…”

Section: Methodsmentioning

confidence: 99%

“…The presence of the trough indicates that a significant fraction of the light in this wavelength range is absorbed by the phosphor. In the range 490 nm < λ i < 520 nm where absorption and emission of phosphor overlap [45], the spectra show a steep rise in the transmission due to the reduced absorption. At wavelengths longer than λ i = 520 nm, the transmission spectra are flat.…”

Section: Diffuse Light Transmission and Reflectionmentioning

confidence: 99%

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Analytical modeling of light transport in scattering materials with strong absorption

Meretska¹,

Uppu²,

Vissenberg³

et al. 2017

Opt. Express

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Abstract:We have investigated the transport of light through slabs that both scatter and strongly absorb, a situation that occurs in diverse application fields ranging from biomedical optics, powder technology, to solid-state lighting. In particular, we study the transport of light in the visible wavelength range between 420 and 700 nm through silicone plates filled with YAG:Ce 3+ phosphor particles, that even re-emit absorbed light at different wavelengths. We measure the total transmission, the total reflection, and the ballistic transmission of light through these plates. We obtain average single particle properties namely the scattering cross-section σ s , the absorption cross-section σ a , and the anisotropy factor µ using an analytical approach, namely the P3 approximation to the radiative transfer equation. We verify the extracted transport parameters using Monte-Carlo simulations of the light transport. Our approach fully describes the light propagation in phosphor diffuser plates that are used in white LEDs and that reveal a strong absorption (L/l a > 1) up to L/l a = 4, where L is the slab thickness, l a is the absorption mean free path. In contrast, the widely used diffusion theory fails to describe this parameter range. Our approach is a suitable analytical tool for industry, since it provides a fast yet accurate determination of key transport parameters, and since it introduces predictive power into the design process of white light emitting diodes. 8190-8204 (2014). 30. To be sure, in a scattering system the degree of scattering is given by L/ s rather than L/ t r . Since in the vast majority of scattering systems the transport mean free paths exceeds the scattering mean free path ( t r ≥ s ) due to predominantly forward scattering [34], we consider our characterization to be on the safe side. 31. S. Chandrasekhar, Radiative transfer (Dover, New York NY, 1960). 32. M. Kaveh, Analogies in optics and micro electronics (Springer, Netherlands, 1991) 33.

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“…The absorption cross section tends to zero at the edges of the absorption spectral range (λ i =420 nm and 520 nm) in agreement with Ref. [45].…”

Section: Diffuse Light Transmission and Reflectionsupporting

confidence: 68%

Section: Diffuse Light Transmission and Reflectionmentioning

confidence: 89%

Section: Methodsmentioning

confidence: 99%

Section: Diffuse Light Transmission and Reflectionmentioning

confidence: 99%

See 2 more Smart Citations

Analytical modeling of light transport in scattering materials with strong absorption

Meretska¹,

Uppu²,

Vissenberg³

et al. 2017

Opt. Express

Self Cite

View full text Add to dashboard Cite

show abstract

“…In the case of light, the knowledge of the energy density distribution is important for applications such as enhanced energy conversion in white LEDs [32][33][34][35][36], efficient light harvesting in solar cells [37][38][39], and controlled illumination in biomedical imaging [40]. To date, only numerical calculations of scalar waves [41][42][43] and a single-realization elastic wave experiment [44] have addressed the energy density distribution of shaped waves inside twodimensional (2D) scattering media.…”

Section: Introductionmentioning

confidence: 99%

Mapping the energy density of shaped waves in scattering media onto a complete set of diffusion modes

Ojambati¹,

Mosk²,

Vellekoop³

et al. 2016

Opt. Express

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Abstract:We show that the spatial distribution of the energy density of optimally shaped waves inside a scattering medium can be described by considering only a few of the lowest eigenfunctions of the diffusion equation. Taking into account only the fundamental eigenfunction, the total internal energy inside the sample is underestimated by only 2%. The spatial distribution of the shaped energy density is very similar to the fundamental eigenfunction, up to a cosine distance of about 0.01. We obtained the energy density inside a quasi-1D disordered waveguide by numerical calculation of the joined scattering matrix. Computing the transmission-averaged energy density over all transmission channels yields the ensemble averaged energy density of shaped waves. From the averaged energy density obtained, we reconstruct its spatial distribution using the eigenfunctions of the diffusion equation. The results from our study have exciting applications in controlled biomedical imaging, efficient light harvesting in solar cells, enhanced energy conversion in solid-state lighting, and low threshold random lasers.

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Systematic Design of the Color Point of a White LED

et al. 2019

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Lighting is a crucial technology that is used every day. The introduction of the white light emitting diode (LED) that consists of a blue LED combined with a phosphor layer, greatly reduces the energy consumption for lighting. Despite the fast-growing market white LED's are still designed using slow, numerical, trial-and-error algorithms. Here we introduce a radically new design principle that is based on an analytical model instead of a numerical approach. Our design model predicts the color point for any combination of design parameters. In addition the model provides the reflection and transmission coefficients -as well as the energy density distribution inside the LEDof the scattered and re-emitted light intensities. To validate our model we performed extensive experiments on an emblematic white LED and found excellent agreement.Our model provides for a fast and efficient design, resulting in reduction of both design and production costs.

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How to distinguish elastically scattered light from Stokes shifted light for solid-state lighting?

Cited by 7 publications

References 42 publications

Analytical modeling of light transport in scattering materials with strong absorption

Analytical modeling of light transport in scattering materials with strong absorption

Mapping the energy density of shaped waves in scattering media onto a complete set of diffusion modes

Systematic Design of the Color Point of a White LED

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