ZIB

Hits per page

hits 1 - 2 | 2 hits

Sorting

Electronic Resource

Ein Molekularstrahldetektor mit Elektronenstoßionisierung und Vierpol-Massenfilter (1963)

Bennewitz, H. G. ; Wedemeyer, R.

Springer

The European physical journal 172 (1963), S. 1-18

add to mindlist on the mindlist

Details

ISSN: 1434-601X

Source: Springer Online Journal Archives 1860-2000

Topics: Physics

Notes: Abstract A molecular beam detector is described which ionizes by electron bombardment. The ions are then separated in a quadrupole mass filter and detected by a multiplier. The special advantages of the mass filter allow a high overall transmission so that every 1000th molecule of the beam is measured as an ion. The ion current due to the residual gas is reduced by a factor of 10−6 for all masses 〉45. These results were achieved without separately pumping or baking out the ionisation chamber. Since magnets are not used the detector is comparatively light and small in size. The smallest detectable beam was found to have a current density of 1,8·10−6 molecules/sec mm2 corresponding to 4·103 molecules/cm3, at a vacuum pressure of 8·10−7 torr in the apparatus, and using a time constant of 1,25 sec.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01378369

Permalink

Library	Location	Call Number	Volume/Issue/Year	Availability

Others were also interested in ...

Paper (German National Licenses)

Fulltext

Electronic Resource

Messung der Anisotropie des van der Waals-Potentials durch Streuung von Molekülen in definiertem Quantenzustand (1964)

Bennewitz, H. G. ; Kramer, K. H. ; Paul, W. ; [et al.]

Springer

The European physical journal 177 (1964), S. 84-110

add to mindlist on the mindlist

Details

ISSN: 1434-601X

Source: Springer Online Journal Archives 1860-2000

Topics: Physics

Notes: Abstract A beam of TlF molecules in the (1,0) rotational state was produced by an electrostatic four pole field. This primary beam was crossed at right angles by a secondary beam in a scattering chamber. By changing the direction of an electric field in the scattering chamber it is possible to produce a (1, 0) or (1, 1) state with respect to the secondary beam direction. In this way it was possible to measure the ratio of the total scattering cross-sections, $$\frac{{Q\left( {1, 1} \right)}}{{Q\left( {1, 0} \right)}}$$ , for He, Ne, Ar, and Kr as scattering gases. The result, which should be independent of the scattering gas, is $$\frac{{Q\left( {1, 1} \right)}}{{Q\left( {1, 0} \right)}} = 1.0133 \pm 20 and 1.0140 \pm 50$$ for Ar and Kr resp., whereas for Ne and He the measured ratios are considerably smaller. The results were interpreted in terms of a van der Waals potential of the form $$V = - \frac{A}{{R^6 }}\left( {1 + q \cos ^2 \Theta } \right)$$ , whereR is the distance between the scattering partners and Θ is the angle between the internuclear axis andR.A andq are constants. With the Schiff approximation it is possible to calculate the scattering cross section as a function of the angle between the internuclear axis and the collision direction. Using the rotator eigenfunctions the ratio of the matrix elements of this function was calculated for various assumed values ofq. The above experimental result for $$\frac{{Q\left( {1, 1} \right)}}{{Q\left( {1, 0} \right)}}$$ for Kr and Ar leads to the anisotropy factor,q=0.40±0.07-A detailed estimate of all interactions contributing to the van der Waals potential shows that it is possible to separate out the dipol-dipol dispersion potential from the observed potential; usingLondon's expression for the dispersion potential of asymmetric molecules one gets for the polarisabilities parallel and perpendicular to the intermolecular axis of the TlF molecule: $$\alpha _ \shortparallel = 7.8 {\AA}^3 $$ and $$\alpha _ \bot = 5.5 {\AA}^3 $$ .

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01375405

Permalink

Library	Location	Call Number	Volume/Issue/Year	Availability

Others were also interested in ...

Paper (German National Licenses)

Fulltext

hits 1 - 2 | 2 hits