reflection (comsol) Search Results


reflection spectra  (COMSOL Inc)
90
COMSOL Inc reflection spectra
Reflection Spectra, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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reflective aluminum layers  (COMSOL Inc)
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COMSOL Inc reflective aluminum layers
The large effect of Al stress can be compensated by deposition of an Al-layer with exactly the same stress values and thickness on the back side. In this case, the low membrane distortion without an aluminum <t>reflective</t> layer is recovered, i.e., the membrane part is almost flat.
Reflective Aluminum Layers, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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structure laser reflection imaging simulation system  (COMSOL Inc)
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COMSOL Inc structure laser reflection imaging simulation system
The large effect of Al stress can be compensated by deposition of an Al-layer with exactly the same stress values and thickness on the back side. In this case, the low membrane distortion without an aluminum <t>reflective</t> layer is recovered, i.e., the membrane part is almost flat.
Structure Laser Reflection Imaging Simulation System, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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m shaped reflectance response  (COMSOL Inc)
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COMSOL Inc m shaped reflectance response
The large effect of Al stress can be compensated by deposition of an Al-layer with exactly the same stress values and thickness on the back side. In this case, the low membrane distortion without an aluminum <t>reflective</t> layer is recovered, i.e., the membrane part is almost flat.
M Shaped Reflectance Response, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulation reflectance plots  (COMSOL Inc)
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COMSOL Inc simulation reflectance plots
Reflection spectrum obtained from COMSOL ® simulations using the RF module. The ‘ Y -peak’ denotes the peak that shifts under Y -axis strains, and ‘ Z -peak’ denotes the peak that shifts under Z -axis strains. ( a ) solid-disc under Z -axis strain; Note the drop in Y -peak <t>reflectance.</t> ( b ) solid-disc under Y -axis strain; note the Y -peak partially overlaps the Z -peak around 15% strain, and moves past it at 25% strain. ( c ) slotted-disc under Z -axis strain; note the drop in reflectivity of the Y -peak. ( d ) slotted-disc under Y -axis strain; there is a significant drop in Z -peak reflectance.
Simulation Reflectance Plots, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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reflectivity rsample(λ, t)  (COMSOL Inc)
90
COMSOL Inc reflectivity rsample(λ, t)
Reflection spectrum obtained from COMSOL ® simulations using the RF module. The ‘ Y -peak’ denotes the peak that shifts under Y -axis strains, and ‘ Z -peak’ denotes the peak that shifts under Z -axis strains. ( a ) solid-disc under Z -axis strain; Note the drop in Y -peak <t>reflectance.</t> ( b ) solid-disc under Y -axis strain; note the Y -peak partially overlaps the Z -peak around 15% strain, and moves past it at 25% strain. ( c ) slotted-disc under Z -axis strain; note the drop in reflectivity of the Y -peak. ( d ) slotted-disc under Y -axis strain; there is a significant drop in Z -peak reflectance.
Reflectivity Rsample(λ, T), supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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reflection luminance of grayscale model  (COMSOL Inc)
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COMSOL Inc reflection luminance of grayscale model
Reflection spectrum obtained from COMSOL ® simulations using the RF module. The ‘ Y -peak’ denotes the peak that shifts under Y -axis strains, and ‘ Z -peak’ denotes the peak that shifts under Z -axis strains. ( a ) solid-disc under Z -axis strain; Note the drop in Y -peak <t>reflectance.</t> ( b ) solid-disc under Y -axis strain; note the Y -peak partially overlaps the Z -peak around 15% strain, and moves past it at 25% strain. ( c ) slotted-disc under Z -axis strain; note the drop in reflectivity of the Y -peak. ( d ) slotted-disc under Y -axis strain; there is a significant drop in Z -peak reflectance.
Reflection Luminance Of Grayscale Model, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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fem calculations of reflectance of metasurfaces using  (COMSOL Inc)
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COMSOL Inc fem calculations of reflectance of metasurfaces using
Structural details of the fabricated <t>metasurfaces.</t> ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.
Fem Calculations Of Reflectance Of Metasurfaces Using, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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s11 reflection coefficient  (COMSOL Inc)
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COMSOL Inc s11 reflection coefficient
Structural details of the fabricated <t>metasurfaces.</t> ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.
S11 Reflection Coefficient, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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ratio between the acoustic intensity (power) reflected to the left by the carpet cloak  (COMSOL Inc)
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COMSOL Inc ratio between the acoustic intensity (power) reflected to the left by the carpet cloak
Structural details of the fabricated <t>metasurfaces.</t> ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.
Ratio Between The Acoustic Intensity (Power) Reflected To The Left By The Carpet Cloak, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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complex reflectance  (COMSOL Inc)
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COMSOL Inc complex reflectance
Structural details of the fabricated <t>metasurfaces.</t> ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.
Complex Reflectance, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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reflectance calculated using  (COMSOL Inc)
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COMSOL Inc reflectance calculated using
Structural details of the fabricated <t>metasurfaces.</t> ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.
Reflectance Calculated Using, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Image Search Results


The large effect of Al stress can be compensated by deposition of an Al-layer with exactly the same stress values and thickness on the back side. In this case, the low membrane distortion without an aluminum reflective layer is recovered, i.e., the membrane part is almost flat.

Journal: Micromachines

Article Title: Evaluation and Optimization of a MOEMS Active Focusing Device

doi: 10.3390/mi12020172

Figure Lengend Snippet: The large effect of Al stress can be compensated by deposition of an Al-layer with exactly the same stress values and thickness on the back side. In this case, the low membrane distortion without an aluminum reflective layer is recovered, i.e., the membrane part is almost flat.

Article Snippet: The reflective aluminum layers were created by adding the “shell” property offered by COMSOL’s Shell physics module to the corresponding surfaces of the device layer.

Techniques: Membrane

Reflection spectrum obtained from COMSOL ® simulations using the RF module. The ‘ Y -peak’ denotes the peak that shifts under Y -axis strains, and ‘ Z -peak’ denotes the peak that shifts under Z -axis strains. ( a ) solid-disc under Z -axis strain; Note the drop in Y -peak reflectance. ( b ) solid-disc under Y -axis strain; note the Y -peak partially overlaps the Z -peak around 15% strain, and moves past it at 25% strain. ( c ) slotted-disc under Z -axis strain; note the drop in reflectivity of the Y -peak. ( d ) slotted-disc under Y -axis strain; there is a significant drop in Z -peak reflectance.

Journal: Sensors (Basel, Switzerland)

Article Title: Axially-Anisotropic Hierarchical Grating 2D Guided-Mode Resonance Strain-Sensor

doi: 10.3390/s19235223

Figure Lengend Snippet: Reflection spectrum obtained from COMSOL ® simulations using the RF module. The ‘ Y -peak’ denotes the peak that shifts under Y -axis strains, and ‘ Z -peak’ denotes the peak that shifts under Z -axis strains. ( a ) solid-disc under Z -axis strain; Note the drop in Y -peak reflectance. ( b ) solid-disc under Y -axis strain; note the Y -peak partially overlaps the Z -peak around 15% strain, and moves past it at 25% strain. ( c ) slotted-disc under Z -axis strain; note the drop in reflectivity of the Y -peak. ( d ) slotted-disc under Y -axis strain; there is a significant drop in Z -peak reflectance.

Article Snippet: The quality factor vs. strain plots ( c,d) were derived from COMSOL ® simulation reflectance plots for 0%–25% strain in steps of 5% strain.

Techniques:

Structural details of the fabricated metasurfaces. ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.

Journal: Scientific Reports

Article Title: Broadband and wide-angle antireflective metasurfaces with complementary patterns

doi: 10.1038/s41598-025-89481-4

Figure Lengend Snippet: Structural details of the fabricated metasurfaces. ( a ) Schematic diagram of preparing metasurface with nanodimple and nanobump designs on PDMS via soft imprint lithography technique. The AFM images of the 3D-PhC, nanodimple layer and nanobump layer are shown as inset in the diagram. ( b, c ) AFM images in 2D view are shown for nanodimple and nanobump metasurfaces respectively. ( d ) Line Profile obtained from the 2D images of the samples. Average height, depth and height respectively of the 3D-PhC, nanodimple and nanobump structures are 121.1 nm, 134.4 nm and 85.3 nm.

Article Snippet: As the cases of Fresnel reflection calculated using the graded index profile (obtained using fill factor from EMT) and FEM calculations of reflectance of metasurfaces using COMSOL used ideal shape of the patterns, these two cases show an increase in reflectance in NIR range.

Techniques:

Analysis of antireflection in metasurfaces. ( a ) Schematic of how the nanodimple and nanobump surfaces are modelled for the calculation of effective refractive index. The black dashed line defines the zero height and zero depth in calculation. ( b ) Variation of effective refractive index with height of nanobump surface (red lines) and depth of nanodimple surface (blue lines), calculated using ideal shape of patterns. ( c ) Reflection spectrum calculated using Fresnel’s equation with the index profile from ( b ). ( d ) Variation of effective refractive index with height of nanobump surface (red lines) and depth of nanodimple surface (blue lines), calculated using real shape of patterns from AFM images. Arrows in ( b ) and ( d ) indicate the y-axis corresponding to the data. ( e ) Reflection spectrum calculated using Fresnel’s equation with the index profile from ( d ). The inset shows the measured data. ( e ) Reflection spectra of nanodimple and nanobump metasurface of equal depth and height obtained from COMSOL calculation. In ( b ) and ( d ), height has positive values while depth has negative values due to the choice of z = 0 in ( a ).

Journal: Scientific Reports

Article Title: Broadband and wide-angle antireflective metasurfaces with complementary patterns

doi: 10.1038/s41598-025-89481-4

Figure Lengend Snippet: Analysis of antireflection in metasurfaces. ( a ) Schematic of how the nanodimple and nanobump surfaces are modelled for the calculation of effective refractive index. The black dashed line defines the zero height and zero depth in calculation. ( b ) Variation of effective refractive index with height of nanobump surface (red lines) and depth of nanodimple surface (blue lines), calculated using ideal shape of patterns. ( c ) Reflection spectrum calculated using Fresnel’s equation with the index profile from ( b ). ( d ) Variation of effective refractive index with height of nanobump surface (red lines) and depth of nanodimple surface (blue lines), calculated using real shape of patterns from AFM images. Arrows in ( b ) and ( d ) indicate the y-axis corresponding to the data. ( e ) Reflection spectrum calculated using Fresnel’s equation with the index profile from ( d ). The inset shows the measured data. ( e ) Reflection spectra of nanodimple and nanobump metasurface of equal depth and height obtained from COMSOL calculation. In ( b ) and ( d ), height has positive values while depth has negative values due to the choice of z = 0 in ( a ).

Article Snippet: As the cases of Fresnel reflection calculated using the graded index profile (obtained using fill factor from EMT) and FEM calculations of reflectance of metasurfaces using COMSOL used ideal shape of the patterns, these two cases show an increase in reflectance in NIR range.

Techniques: Refractive Index