The Next Generation of Colloidal Probes: A Universal Approach for Soft and Ultra‐Small Particles
Abstract: The colloidal probe technique, which is based on the atomic force microscope, revolutionizes direct force measurements in many fields, such as interface science or biomechanics. It allows for the first time to determine interaction forces on the single particle or cell level. However, for many applications, important “blind spots” remain, namely, the possibility to probe interaction potentials for nanoparticles or complex colloids with a soft outer shell. Definitely, these are colloidal systems that are currently of major industrial importance and interest from theory. The here‐presented novel approach allows for overcome the aforementioned limitations. Its applicability has been demonstrated for 300 nm sized carboxylate‐modified latex particles as well as sub‐micron core–shell particles with a soft poly‐N‐isopropylacrylamide hydrogel shell and a rigid silica core. For the latter, which until now cannot be studied by the colloidal probe technique, determined is the temperature dependency of electrosteric and adhesion forces has been determined on the single particle level.
- Standort
-
Deutsche Nationalbibliothek Frankfurt am Main
- Umfang
-
Online-Ressource
- Sprache
-
Englisch
- Erschienen in
-
The Next Generation of Colloidal Probes: A Universal Approach for Soft and Ultra‐Small Particles ; volume:15 ; number:43 ; year:2019 ; extent:11
Small ; 15, Heft 43 (2019) (gesamt 11)
- Urheber
-
Mark, Andreas
Helfricht, Nicolas
Rauh, Astrid
Karg, Matthias
Papastavrou, Georg
- DOI
-
10.1002/smll.201902976
- URN
-
urn:nbn:de:101:1-2022072906393922371789
- Rechteinformation
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Letzte Aktualisierung
-
15.08.2025, 07:35 MESZ
Datenpartner
Deutsche Nationalbibliothek. Bei Fragen zum Objekt wenden Sie sich bitte an den Datenpartner.
Beteiligte
- Mark, Andreas
- Helfricht, Nicolas
- Rauh, Astrid
- Karg, Matthias
- Papastavrou, Georg
Ähnliche Objekte (12)
The Next Generation of Colloidal Probes : A Universal Approach for Soft and Ultra‐Small Particles
Membrane fusion studied by colloidal probes
Soft Colloidal Probes : Hydrogelpartikel als biomimetische Biosensoren
Pattern deposition of colloidal particles
Acoustic propulsion of colloidal particles
Colloidal particles on quasicrystalline substrates
A general strategy for colloidal stable ultrasmall amorphous mineral clusters in organic solvents
Flavor probes of axion-like particles
Collider probes of axion-like particles
Higgs probes of axion-like particles
Anisotropic particles for colloidal self-assembly
Synthesis and characterization of anisotropic colloidal particles
The Next Generation of Colloidal Probes : A Universal Approach for Soft and Ultra‐Small Particles
Membrane fusion studied by colloidal probes
Soft Colloidal Probes : Hydrogelpartikel als biomimetische Biosensoren
Pattern deposition of colloidal particles
Acoustic propulsion of colloidal particles
Colloidal particles on quasicrystalline substrates
A general strategy for colloidal stable ultrasmall amorphous mineral clusters in organic solvents
Flavor probes of axion-like particles
Collider probes of axion-like particles
Higgs probes of axion-like particles
Anisotropic particles for colloidal self-assembly
Synthesis and characterization of anisotropic colloidal particles
The Next Generation of Colloidal Probes : A Universal Approach for Soft and Ultra‐Small Particles
Membrane fusion studied by colloidal probes
Soft Colloidal Probes : Hydrogelpartikel als biomimetische Biosensoren
Pattern deposition of colloidal particles
Acoustic propulsion of colloidal particles
Colloidal particles on quasicrystalline substrates
A general strategy for colloidal stable ultrasmall amorphous mineral clusters in organic solvents
Flavor probes of axion-like particles
Collider probes of axion-like particles
Higgs probes of axion-like particles
Anisotropic particles for colloidal self-assembly