Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
about
Graphene-Based Microbots for Toxic Heavy Metal Removal and Recovery from WaterDesigning Micro- and Nanoswimmers for Specific ApplicationsFabrication and Wettability Study of WO3 Coated Photocatalytic Membrane for Oil-Water Separation: A Comparative Study with ZnO Coated MembraneCatalytically powered dynamic assembly of rod-shaped nanomotors and passive tracer particles.Self-propelled micromotors for cleaning polluted water.3D printed self-driven thumb-sized motors for in-situ underwater pollutant remediation.Catalytic nanomotors for environmental monitoring and water remediation.Bipolar electrochemistry.Chemical energy powered nano/micro/macromotors and the environment.Chemically powered micro- and nanomotors.A Force to Be Reckoned With: A Review of Synthetic Microswimmers Powered by Ultrasound.Utilizing Iron's Attractive Chemical and Magnetic Properties in Microrocket Design, Extended Motion, and Unique Performance.Fuel-Free Synthetic Micro-/Nanomachines.Trapping self-propelled micromotors with microfabricated chevron and heart-shaped chips.Improving catalase-based propelled motor endurance by enzyme encapsulation.Marangoni self-propelled capsules in a maze: pollutants 'sense and act' in complex channel environments.Poisoning of bubble propelled catalytic micromotors: the chemical environment matters.Self-propelled nanojets via template electrodeposition.Motion-based, high-yielding, and fast separation of different charged organics in water.Fabricating Superhydrophobic Polymeric Materials for Biomedical Applications.Motion-based threat detection using microrods: experiments and numerical simulations.Thermal activation of catalytic microjets in blood samples using microfluidic chips.Effect of surfactants on the performance of tubular and spherical micromotors - a comparative study.Stimuli-responsive microjets with reconfigurable shape.Self-propelled activated carbon Janus micromotors for efficient water purification.Challenges of the movement of catalytic micromotors in blood.Micromotor-based lab-on-chip immunoassays.Nanomotor-based biocatalytic patterning of helical metal microstructures.Influence of real-world environments on the motion of catalytic bubble-propelled micromotors.Seawater-driven magnesium based Janus micromotors for environmental remediation.Self-propelled micromotors driven by the magnesium-water reaction and their hemolytic properties.Reynolds numbers influence the directionality of self-propelled microjet engines in the 10(-4) regime.Corrosion of self-propelled catalytic microengines.Dry-released nanotubes and nanoengines by particle-assisted rolling.Nanomotors responsive to nerve-agent vapor plumes.Efficient biocatalytic degradation of pollutants by enzyme-releasing self-propelled motors.Efficient bubble propulsion of polymer-based microengines in real-life environments.Multi-fuel driven Janus micromotors.Template electrodeposition of catalytic nanomotors.Nanomotor dynamics in a chemically oscillating medium.
P2860
Q27300855-5E72DD80-BC34-45FF-82CE-215BF726ADE9Q28818795-8BF56801-88C8-4AB8-B5DA-4D915182EE75Q29994707-857BCA0D-B200-4B7C-ABD4-424772524225Q30439492-62B263F1-2E51-4751-8120-77F7546A952BQ30445356-7131CB26-86D9-40EA-B3DC-C22EE6ACA79EQ30838843-F986F03C-5007-4014-95BD-8EE747D11AC2Q33842131-1B451A12-BFD4-4DEE-983D-F724765334E7Q38120713-63E57F92-3A22-47F9-9950-420811FDB486Q38269770-031B7231-77A2-46BE-9CEB-EFE9E4D4731BQ38287505-AD05B2F4-C7D5-4CF9-9AF6-1F5741007031Q38410405-27B4F3B2-542C-4E4E-B049-BEECF06B80B7Q38732500-FBA416A4-17E0-4E1B-AFBE-75041E8B76C4Q38777722-54FD69BC-E94D-489D-8F1C-07ACA5437119Q39107332-0449B098-A53D-493B-8621-877F6CCD326DQ39169977-2235E8C0-721B-480D-8D4D-B923CFE7F29BQ39179915-FCA81AA6-C628-498E-B0CD-DCF8B926ACC6Q39459373-5691D967-0B30-465C-AB2E-414D8A480862Q39539215-389FB1D4-B3D7-4D58-910B-7934A28CFF2FQ40236318-75C7F02B-BF10-44F6-BC87-4BB8FC6EE115Q40526464-EDFAAD62-0D91-4954-A9FD-7ABA506573A7Q41100845-387F5F86-5CF8-42DF-A914-DFF45C8BD822Q41810662-8177EA4A-8188-49CB-A057-740885A46352Q42967474-C9032598-06A9-438E-9E7F-D4F2CF54939DQ43054701-AB2FD9FC-1F98-4C0C-AD4D-B508D0409F24Q43322968-D472F5F8-F68C-42E5-B0CA-3C9109F598D9Q43448870-A6B48FE7-566C-432D-A7E6-79DAFAA4706FQ43530718-847532AC-6AE5-4227-922A-B33BD8B4B237Q43626406-346B17C7-94B1-4B23-B234-2E9140C43ECEQ43696350-D3FC41BC-7A9C-431F-848F-38E47F25A9C7Q44029308-F30C52BF-38D8-4ACA-92DC-2F485AC4DE00Q44410429-741D7A41-00FA-4833-9B4F-9FC0CD911F91Q45133355-CF01050E-23CB-4838-B3D9-180D35C0F8FEQ45171110-C963FFA3-968B-4906-B9F0-7CFEF20398A8Q45769690-8EC86687-6848-4362-8E48-82C2DA42C233Q45990856-1B0436DA-8149-4FB5-AA8A-DD52FF834CF6Q45995816-87FF7368-5D2D-485D-BCE7-97D84D231CAEQ46051384-06F18766-5F0E-47B2-98DF-4621805C6478Q46254226-8FB2B1E8-2B84-4010-91E3-DC651379A2F3Q46417457-940F0B6C-DF38-428D-A124-E63F6E096401Q46738736-A3D67DC0-676E-482C-9872-D0E1CE1C44A2
P2860
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh-hant
name
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@en
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@nl
type
label
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@en
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@nl
prefLabel
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@en
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@nl
P2093
P50
P356
P1433
P1476
Superhydrophobic alkanethiol-coated microsubmarines for effective removal of oil.
@en
P2093
Alberto Escarpa
Joseph Wang
Maria Guix
Miguel García
P304
P356
10.1021/NN301175B
P407
P577
2012-04-10T00:00:00Z