microscope platform Search Results


fixed stage microscope  (Siskiyou Corporation)
86
Siskiyou Corporation fixed stage microscope
Fixed Stage Microscope, supplied by Siskiyou Corporation, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/fixed stage microscope/product/Siskiyou Corporation
Average 86 stars, based on 1 article reviews
fixed stage microscope - by Bioz Stars, 2026-03
86/100 stars
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stellaris 8 confocal microscope  (Danaher Inc)
96
Danaher Inc stellaris 8 confocal microscope
Stellaris 8 Confocal Microscope, supplied by Danaher Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/stellaris 8 confocal microscope/product/Danaher Inc
Average 96 stars, based on 1 article reviews
stellaris 8 confocal microscope - by Bioz Stars, 2026-03
96/100 stars
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las x life science microscope software  (Danaher Inc)
96
Danaher Inc las x life science microscope software
Las X Life Science Microscope Software, supplied by Danaher Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/las x life science microscope software/product/Danaher Inc
Average 96 stars, based on 1 article reviews
las x life science microscope software - by Bioz Stars, 2026-03
96/100 stars
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leica stellaris confocal microscope  (Danaher Inc)
96
Danaher Inc leica stellaris confocal microscope
Leica Stellaris Confocal Microscope, supplied by Danaher Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/leica stellaris confocal microscope/product/Danaher Inc
Average 96 stars, based on 1 article reviews
leica stellaris confocal microscope - by Bioz Stars, 2026-03
96/100 stars
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stereo microscope platform  (Evident Corporation)
98
Evident Corporation stereo microscope platform
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Stereo Microscope Platform, supplied by Evident Corporation, used in various techniques. Bioz Stars score: 98/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/stereo microscope platform/product/Evident Corporation
Average 98 stars, based on 1 article reviews
stereo microscope platform - by Bioz Stars, 2026-03
98/100 stars
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tie inverted optical microscope platform  (Nikon)
99
Nikon tie inverted optical microscope platform
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Tie Inverted Optical Microscope Platform, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/tie inverted optical microscope platform/product/Nikon
Average 99 stars, based on 1 article reviews
tie inverted optical microscope platform - by Bioz Stars, 2026-03
99/100 stars
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inverted microscope platform  (Evident Corporation)
99
Evident Corporation inverted microscope platform
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Inverted Microscope Platform, supplied by Evident Corporation, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/inverted microscope platform/product/Evident Corporation
Average 99 stars, based on 1 article reviews
inverted microscope platform - by Bioz Stars, 2026-03
99/100 stars
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axio observerz1 platform microscope  (Carl Zeiss)
99
Carl Zeiss axio observerz1 platform microscope
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Axio Observerz1 Platform Microscope, supplied by Carl Zeiss, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/axio observerz1 platform microscope/product/Carl Zeiss
Average 99 stars, based on 1 article reviews
axio observerz1 platform microscope - by Bioz Stars, 2026-03
99/100 stars
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microscope microbial genome annotation and analysis platform (mage)  (Genoscope)
90
Genoscope microscope microbial genome annotation and analysis platform (mage)
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Microscope Microbial Genome Annotation And Analysis Platform (Mage), supplied by Genoscope, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/microscope microbial genome annotation and analysis platform (mage)/product/Genoscope
Average 90 stars, based on 1 article reviews
microscope microbial genome annotation and analysis platform (mage) - by Bioz Stars, 2026-03
90/100 stars
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microscope annotation platform  (Genoscope)
90
Genoscope microscope annotation platform
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Microscope Annotation Platform, supplied by Genoscope, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/microscope annotation platform/product/Genoscope
Average 90 stars, based on 1 article reviews
microscope annotation platform - by Bioz Stars, 2026-03
90/100 stars
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microscope platform  (Genoscope)
90
Genoscope microscope platform
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Microscope Platform, supplied by Genoscope, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/microscope platform/product/Genoscope
Average 90 stars, based on 1 article reviews
microscope platform - by Bioz Stars, 2026-03
90/100 stars
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atomic force microscope ntegra platform  (Nanosurf Inc)
90
Nanosurf Inc atomic force microscope ntegra platform
Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted <t>microscope,</t> see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).
Atomic Force Microscope Ntegra Platform, supplied by Nanosurf Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/atomic force microscope ntegra platform/product/Nanosurf Inc
Average 90 stars, based on 1 article reviews
atomic force microscope ntegra platform - by Bioz Stars, 2026-03
90/100 stars
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Image Search Results


Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted microscope, see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).

Journal: Advanced Science

Article Title: Sub‐Nanogram Resolution Measurement of Inertial Mass and Density Using Magnetic‐Field‐Guided Bubble Microthruster

doi: 10.1002/advs.202403867

Figure Lengend Snippet: Illustration of the BMT principle. The principle relies on the transient velocity variation of the target microparticle in response to the inertial impact from the bubble collapse when a JM–bubble–particle configuration is established. a) Schematic diagram illustrating the three‐stage velocity variation V p of the target microparticle. In stage I (red), the microparticle retracts into the bubble cavity following the collapse. In stage II (blue), the transient hydrodynamic flow propels the microparticle strongly, resulting in a positive change in velocity. In stage III (green), the microparticle gradually decelerates as it interacts with the surrounding fluid flow. The dashed curve depicts the decay of the ambient fluid velocity u f . b) Measured velocity variation during stages II and III of a microparticle (with radius R p = 6.4 µm, density ρ p = 0.66 g cm −3 ) impacted by the BMT, compared with the dashed curve obtained from numerical simulation, indicating good agreement. c) Experimental snapshots (bottom view from the inverted microscope, see SM Video (Supporting Information), recorded by an ultra‐high‐speed camera at 450 000 fps) capturing a BMT during bubble collapse, with white circles denoting the initial position of the target microparticle. d) Snapshots from numerical simulation showing the flow field and the motion of the microparticle at the same times as in (c). The red dashed circles display the original positions of the JM and the microparticle. The simulation perfectly reproduces the motions of both JM and the microparticle in experiment shown in (c).

Article Snippet: Embryo extraction and transfer were performed using homemade glass capillary tubes under a stereo microscope platform (Olympus SZX16).

Techniques: Inverted Microscopy