Max-Planck-Institut für Kolloid- und Grenzflächenforschung, Potsdam

STARTSEITE

Über das Institut

Biomaterialien

Biomolekulare Systeme

Grenzflächen

Kolloidchemie

Theorie & Bio-Systeme

IMPRS - Research School

Geräteausstattung

General Overview

There is a number of instruments for measuring the static and dynamic surface and interfacial tension of solutions, spanning over a large time interval from less than 1 ms up to several h:

Ring tensiometer TD1
Automatic Ring Tensiometer TE2
Drop Volume Tensiometer TVT2
Bubble Pressure Tensiometer MPT2, BPA-1P
Pendent/Sessile Drop Method PAT1, PAT2-USB
Drop Pressure Method DPA1

Investigations of the interfacial dilational and shear rheology are performed with the following methods:

transient relaxations with the pendent drop or drop pressure set-up
higher frequency harmonic oscillations with the oscillating/drop/bubble apparatus
low frequency harmonic oscillations with the oscillating barrier trough
low frequency harmonic damped shear oscillations with the interfacial shear rheometer
higher frequency forced shear oscillations with the interfacial shear rheometer

To study the dilational rheology of interfacial layers a series of instruments, essentially designed at the MPI, are used. The reason for the variety of instruments is the need to cover a broad frequency range, i.e. to be able to identify characteristic times of various relaxation processes. For slow oscillation experiments we use the drop and bubble shape technique, which allows measurements from 0.001 to 1 Hz. Also the oscillating barrier method works in this time range. Experiments at frequencies up to 200 Hz and above can be performed with the oscillating drop/bubble method. The application of the capillary wave method gives access even to frequencies up to about 1000 Hz. The advantage of the drop/bubble methods is that they are applicable also to liquid/liquid interfaces.

For studies of the shear rheology we have a torsion shear rheometer ISR 1 which allows studies at the liquid/air and liquid/liquid interface. It is designed such that very low shear viscosities can be measured, however, it does not work for standard surfactant solutions (too small viscosities). Equipped with a Langmuir trough, it can be used also for studies of spread layers. Variation of the frequency (around 0.1 Hz) is possible by using different torsion wires. Forced shear oscillations at higher frequencies at the liquid/air and liquid/liquid interface can be performend with a sensitive commercial rheometer (Paar-Physica) equipt with the biconical disk interfacial cell geometry.

Other techniques used for the studies are a capillary viscosimeter from Lauda for the measurement of bulk viscosity, the ellipsometer from Optrel for measurements of the surface layer thickness, and the Brewster Angle Microscope from Optrel for studies of monolayer structures.

Force Methods Tensiometer (TD1 from LAUDA)	J. Krägel
Drop Volume Tensiometer (TVT 2 from LAUDA)	J. Krägel
Interfacial Shear Rheometer (ISR 1 (torsion pendulum technique) from SINTERFACE)	J. Krägel
Interfacial Shear Rheometer (MCR 301 - IRS from Paar-Physica)	J. Krägel
Viscosity Measuring System (PVS 1 from LAUDA)	J. Krägel
Capillary Wave Damping Spectroscopy (built at the MPI)	Dmitri Grigoriev
Multiscope and Brewster Angle Microscope (from OPTREL)	Dmitri Grigoriev
Oscillating Barrier Trough (built at the MPI)	Dmitri Grigoriev
Automatic Ring Tensiometer (TE 2 C and TE 3 C from LAUDA)	A. V. Makievski
Maximum Bubble Pressure Tensiometer (MPT 2 from LAUDA)	A. V. Makievski
Maximum Bubble Pressure Tensiometer (BPA 1P from SINTERFACE)	A. V. Makievski
Profile Analysis Tensiometer and Transient Relaxation Methods (PAT 1 from SINTERFACE)	A. V. Makievski
Oscillating Drop/Bubble Rheometer (ODBA 1 from SINTERFACE)	J. Krägel
Drop Pressure Analyser (DPA 1 from SINTERFACE)	J. Krägel
Longitudinal Wave Damping Spectroscopy (will be built at the MPI)	Dmitri Grigoriev
Capillary Pressure Tensiometer (DPA1 from SINTERFACE)	J. Krägel