Introducing Novel Planar Micromixers with Pillars and Gaps and Studying the Impact of Various Geometric Parameters on the Efficiency of Micromixers
Chemical bioreactions play a significant role in many of the microfluidic devices, and their applications in biomedical science have seen substantial growth. Given that effective mixing is vital for initiating biochemical reactions in many applications, micromixers have become increasingly prevalent...
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| creator | Barzoki, Ali Kheirkhah |
| description | Chemical bioreactions play a significant role in many of the microfluidic
devices, and their applications in biomedical science have seen substantial
growth. Given that effective mixing is vital for initiating biochemical
reactions in many applications, micromixers have become increasingly prevalent
for high-throughput assays. In this study, numerical study is conducted to
examine the fluid flow and mass transfer characteristics in novel micromixers
featuring an array of pillars. The study explores the effects of pillar array
design on mixing performance and pressure drop, drawing from principles such as
contraction-expansion and split-recombine. Two configurations of pillar arrays
are introduced, each undergoing investigation regarding parameters such as
pillar diameter, gap size between pillar groups, distance between pillars, and
vertical shift in pillar groups. Subsequently, optimal micromixers are
identified, exhibiting mixing efficiency exceeding 99.7% at moderate Reynolds
number (Re = 1), a level typically challenging for micromixers to attain high
mixing efficiency. Notably, the pressure drop remains low at 1102 Pa.
Furthermore, the variations in mixing index over time and across different
positions along the channel are examined. Both configurations demonstrate short
mixing lengths and times. The combination of rapid mixing, low pressure drop,
and short mixing length positions the novel micromixers as highly promising for
microfluidic applications. |
| doi_str_mv | 10.48550/arxiv.2402.07854 |
| format | Article |
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devices, and their applications in biomedical science have seen substantial
growth. Given that effective mixing is vital for initiating biochemical
reactions in many applications, micromixers have become increasingly prevalent
for high-throughput assays. In this study, numerical study is conducted to
examine the fluid flow and mass transfer characteristics in novel micromixers
featuring an array of pillars. The study explores the effects of pillar array
design on mixing performance and pressure drop, drawing from principles such as
contraction-expansion and split-recombine. Two configurations of pillar arrays
are introduced, each undergoing investigation regarding parameters such as
pillar diameter, gap size between pillar groups, distance between pillars, and
vertical shift in pillar groups. Subsequently, optimal micromixers are
identified, exhibiting mixing efficiency exceeding 99.7% at moderate Reynolds
number (Re = 1), a level typically challenging for micromixers to attain high
mixing efficiency. Notably, the pressure drop remains low at 1102 Pa.
Furthermore, the variations in mixing index over time and across different
positions along the channel are examined. Both configurations demonstrate short
mixing lengths and times. The combination of rapid mixing, low pressure drop,
and short mixing length positions the novel micromixers as highly promising for
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devices, and their applications in biomedical science have seen substantial
growth. Given that effective mixing is vital for initiating biochemical
reactions in many applications, micromixers have become increasingly prevalent
for high-throughput assays. In this study, numerical study is conducted to
examine the fluid flow and mass transfer characteristics in novel micromixers
featuring an array of pillars. The study explores the effects of pillar array
design on mixing performance and pressure drop, drawing from principles such as
contraction-expansion and split-recombine. Two configurations of pillar arrays
are introduced, each undergoing investigation regarding parameters such as
pillar diameter, gap size between pillar groups, distance between pillars, and
vertical shift in pillar groups. Subsequently, optimal micromixers are
identified, exhibiting mixing efficiency exceeding 99.7% at moderate Reynolds
number (Re = 1), a level typically challenging for micromixers to attain high
mixing efficiency. Notably, the pressure drop remains low at 1102 Pa.
Furthermore, the variations in mixing index over time and across different
positions along the channel are examined. Both configurations demonstrate short
mixing lengths and times. The combination of rapid mixing, low pressure drop,
and short mixing length positions the novel micromixers as highly promising for
microfluidic applications.</description><subject>Physics - Fluid Dynamics</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNpNkMFOhDAQhnvxYFYfwJN9ARBKKfRoNiuSrErixisZy9RtApQUWJfn8IUF1oOn-SeZ_5_8HyF3YeDzNI6DB3Bnc_IZD5gfJGnMr8lP3g7OVqMy7Rd9tSesaVFDC46-GOVsY87oevpthiMtTF3DvEBb0Qy6i3gfxmpavMMRad50oAZqNf0AZ-zY0wxtg4MzihbgYJZLmm3X653WRhls1bQ4_r27IVca6h5v_-aGHJ52h-2zt3_L8u3j3gORcI9VSmPKQiERhFBCfoowReA6CFkQI9coFZNhJJgWbG6rJE81RJhAqhPJo2hD7i-xK5Wyc6YBN5ULnXKlE_0CeWFiOg</recordid><startdate>20240212</startdate><enddate>20240212</enddate><creator>Barzoki, Ali Kheirkhah</creator><scope>GOX</scope></search><sort><creationdate>20240212</creationdate><title>Introducing Novel Planar Micromixers with Pillars and Gaps and Studying the Impact of Various Geometric Parameters on the Efficiency of Micromixers</title><author>Barzoki, Ali Kheirkhah</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a674-2dcfe82169ea66c69b618ea4f01205e4fe9c291362f62078c948fa3e7a8f79433</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2024</creationdate><topic>Physics - Fluid Dynamics</topic><toplevel>online_resources</toplevel><creatorcontrib>Barzoki, Ali Kheirkhah</creatorcontrib><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Barzoki, Ali Kheirkhah</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Introducing Novel Planar Micromixers with Pillars and Gaps and Studying the Impact of Various Geometric Parameters on the Efficiency of Micromixers</atitle><date>2024-02-12</date><risdate>2024</risdate><abstract>Chemical bioreactions play a significant role in many of the microfluidic
devices, and their applications in biomedical science have seen substantial
growth. Given that effective mixing is vital for initiating biochemical
reactions in many applications, micromixers have become increasingly prevalent
for high-throughput assays. In this study, numerical study is conducted to
examine the fluid flow and mass transfer characteristics in novel micromixers
featuring an array of pillars. The study explores the effects of pillar array
design on mixing performance and pressure drop, drawing from principles such as
contraction-expansion and split-recombine. Two configurations of pillar arrays
are introduced, each undergoing investigation regarding parameters such as
pillar diameter, gap size between pillar groups, distance between pillars, and
vertical shift in pillar groups. Subsequently, optimal micromixers are
identified, exhibiting mixing efficiency exceeding 99.7% at moderate Reynolds
number (Re = 1), a level typically challenging for micromixers to attain high
mixing efficiency. Notably, the pressure drop remains low at 1102 Pa.
Furthermore, the variations in mixing index over time and across different
positions along the channel are examined. Both configurations demonstrate short
mixing lengths and times. The combination of rapid mixing, low pressure drop,
and short mixing length positions the novel micromixers as highly promising for
microfluidic applications.</abstract><doi>10.48550/arxiv.2402.07854</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Fluid Dynamics |
| title | Introducing Novel Planar Micromixers with Pillars and Gaps and Studying the Impact of Various Geometric Parameters on the Efficiency of Micromixers |
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