Relation between electrical mobility, mass, and size for nanodrops 1-6.5 nm in diameter in air
about
Inhalation exposure to carbon nanotubes (CNT) and carbon nanofibers (CNF): methodology and dosimetryIon-pair evaporation from ionic liquid clusters.Modeling vapor uptake induced mobility shifts in peptide ions observed with transversal modulation ion mobility spectrometry-mass spectrometry.Ion mobility spectrometry-mass spectrometry examination of the structures, stabilities, and extents of hydration of dimethylamine-sulfuric acid clusters.Comparison of the SAWNUC model with CLOUD measurements of sulphuric acid-water nucleation.Measuring the effect of ion-induced drift-gas polarization on the electrical mobilities of multiply-charged ionic liquid nanodrops in air.Analysis of heterogeneous water vapor uptake by metal iodide cluster ions via differential mobility analysis-mass spectrometry.Measurement of the nucleation of atmospheric aerosol particles.Electrical mobilities of multiply charged ionic-liquid nanodrops in air and carbon dioxide over a wide temperature range: influence of ion-induced dipole interactions.Gas molecule scattering & ion mobility measurements for organic macro-ions in He versus N2 environments.Understanding the mobility of nonspherical particles in the free molecular regime.Effect of ions on sulfuric acid-water binary particle formation: 2. Experimental data and comparison with QC-normalized classical nucleation theoryHigh-Resolution Mobility and Mass Spectrometry of Negative Ions Produced in a241Am Aerosol ChargerRemarks on Ion Generation for CPC Detection Efficiency Studies in Sub-3-nm Size RangeAn Instrumental Comparison of Mobility and Mass Measurements of Atmospheric Small IonsA Medium Flow, High-Resolution Vienna DMA Running in Recirculating ModeFirst Measurements of Neutral Atmospheric Cluster and 1–2 nm Particle Number Size Distributions During Nucleation EventsThe Function-Updated Millikan Model: A Tool for Nanometer Particle Size-Mobility ConversionsCharacterization of nanosized silica size standardsDetection near 1-nm with a laminar-flow, water-based condensation particle counterA bipolar electrospray source of singly charged salt clusters of precisely controlled compositionDesign Considerations and Performance Evaluation of a Compact Aerosol Particle Mass AnalyzerThe Mobility–Volume Relationship below 3.0 nm Examined by Tandem Mobility–Mass MeasurementEffect of Nucleation Temperature on Detecting Molecular Ions and Charged Nanoparticles with a Diethylene Glycol-Based Particle Size MagnifierModification of Laminar Flow Ultrafine Condensation Particle Counters for the Enhanced Detection of 1 nm Condensation NucleiDetermination of the Scalar Friction Factor for Nonspherical Particles and Aggregates Across the Entire Knudsen Number Range by Direct Simulation Monte Carlo (DSMC)
P2860
Q23913295-25A7CD19-A850-4D93-AE38-F70A7DE7F675Q33446328-5E5C64B8-15CB-41A4-9D5D-2EE60EFDD14DQ33465228-1C76A02F-8008-49A0-8AA5-A476AABC8B4CQ33468559-90E2F497-B760-44CD-86A8-BA6186998E7FQ33469905-C05C961C-AD07-40AC-90DB-592C80EB49BCQ45962319-3B44D4A9-65FE-4F22-B0B8-E065B8C990B3Q46669155-9FE37C10-3AD8-417D-A15F-641E2C2F263BQ47254146-D45E6A49-C027-4C01-8D8E-4017974B70CEQ48832725-C2DBF8F8-B943-407E-B1BD-2189B43B12E0Q53231250-B2EA51D9-47AA-4ECC-88DC-3C9191623232Q53402327-616D445C-41CD-462B-9E6F-0C4499EE7BB1Q56944544-7E079D41-D3D3-42F8-A8A9-760B588462EEQ57689052-6C7A7D50-118C-4A5E-BF39-A22056338CC8Q57689367-17FDEEA2-44D3-4ED6-AAD9-427C5BFA6487Q57689573-BCFA3114-7304-48D2-B7E9-C1F818C62DD7Q58094691-63B12D4E-A32F-461B-BF78-553969F906EAQ58094719-C5C2CA05-96D8-4F12-A3CA-66BA8FEE8E7DQ58094803-0D4C8781-3756-4E5B-B392-DBDA1DEF26CDQ58095937-C37B049A-D61C-46DC-8555-C0F9F00D1B53Q58096204-AA13423F-98EE-4F94-91F3-0498EE9197B8Q58142151-4A195699-31C3-4424-B65D-B3B4F841422CQ58150304-8DF5042E-9EA0-4E8B-B8FD-485EEBD4677DQ58160302-4BB3EF31-6D64-42E1-8633-66C4BBCFFCB4Q58248066-0BB3EEEF-BE90-4B20-B015-58CF2FF92987Q58256606-9FB57B33-509E-4F3E-B077-F1452D54860CQ58261376-62A5481C-C9CF-49AC-A134-A147976F67E6
P2860
Relation between electrical mobility, mass, and size for nanodrops 1-6.5 nm in diameter in air
description
2009 nî lūn-bûn
@nan
2009 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@ast
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en-gb
type
label
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@ast
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en-gb
prefLabel
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@ast
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en-gb
P2860
P921
P1476
Relation between electrical mo ...... ps 1-6.5 nm in diameter in air
@en
P2093
Juan Fernandez de la Mora
P2860
P2880
P304
P356
10.1080/02786820802590510
P577
2009-02-25T00:00:00Z