Coaxial probe method

Coaxial Probe Method and Modified Coaxial Probe Method [11, 12]... 

A coaxial probe can also be used to measure the through-plane conductivity of membranes. Figure 5.15 shows the schematic for a coaxial conductivity measurement cell. In this method, the membrane is cut to the same size as the inner conductor, and the measured resistance is the through-plane resistance. The resulting conductivity, 2.4 x 10 2 S/cm, is close to that reported in the literature. 

Often, free-space methods are complementary to use of the waveguide, coaxial, cavity, one-horn interferometer or open-ended coaxial probe. Indeed, due to their heterogeneity, small composite samples arc not representative of the whole material and ffee-space methods are non-destnictive and contactless. They are also suitable for complex permittivity and permeability measurements under high temperature conditions. 

In continuos flow FAB (CFFAB) [7,24,47] the analyte-matrix mixture is delivered continuously to the probe tip through a fused silica capillary which terminates at the probe tip. This configuration provides a means of coupling liquid phase separation techniques with FAB-MS. Addition of the matrix to the analyte solution is accomplished by one of two methods. (1) The matrix is added at concentrations of 5-10% to the mobile phase, and the column effluent is directly fluxed into the CFFAB ion source or (2) column effluent and matrix solution are delivered independently to the probe tip by a coaxial arrangement of two concentric fused silica capillaries. 

We have developed a novel ultrasensitive detection method, thermal lens microscopy (TLM), for nonfluorescent species [13]. TLM is photothermal spectroscopy under an optical microscope. Our thermal lens microscope (TLM) has a dual-beam configuration excitation and probe beams [13]. The wavelength of the excitation beam is selected to coincide with an absorption band of the target molecule and that of the probe beam is chosen to be where the sample solution (both solvent and solute) has no absorption. For example, in determination of methyl red dye in water, cyclohexane, and n-octanol, a 514-nm emission line of an argon-ion laser and a 633-nm emission line of a helium-neon laser were used as excitation and probe beams, respectively [21], Figure 4 shows the configuration and principle of TLM [13]. The excitation beam was modulated at 1 kHz by an optical chopper. After the beam diameters were expanded, the excitation and probe beams were made coaxial by a dichroic mirror just before they were introduced into an objective lens whose magnification and numerical aper-... 

The form of SThM most relevant to the subject of this discussion is carried out using near-field electrical resistance thermometry, and this method has been adopted in the work reported in this chapter. This is because miniaturized resistive probes have the considerable advantage that they can be used both in passive mode as a thermometer and as an active heat source. This enables local thermal analysis (L-TA see text below) as well as SThM to be carried out. At present the most common type of resistive probe available is the Wollaston or Wollaston Wire probe, developed by Dinwiddle et al. (1994) and first used by Balk et al. (1995) and Hammiche et al. (19%a) The construction details of this probe are illustrated in Fig. 7.3. A loop of 75-pm-diameter coaxial bimetallic Wollaston wire is bent into a sharp V-shaped loop. The wire consists of a central 5-pm-diameter platinum/10% rhodium alloy core surrounded by silver. The loop is stabilized with a small bead of epoxy resin deposited approximately 500 pm from its apex. The probe tip or sensor is made... 

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