Berlin 2001 – wissenschaftliches Programm

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AMPD: EPS AMPD

AMPD 1: Sitzung 1

AMPD 1.3: Vortrag

Montag, 2. April 2001, 11:55–12:20, H105

The electronic properties of C₆₀ as obtained from collision experiments — •H. Cederquist¹, B.A. Huber², A. Fardi¹, P. Hvelplund³, J. Jensen⁴, H. Lebius², H.T. Schmidt¹, S. Tomita³, and H. Zettergren¹ — ¹Stockholm University, Frescativ. 24, S-104 05 Stockholm, Sweden — ²Département de Recherche Fondamentale sur la Matiere Condensée/S12A GIM–Grenoble, 17 rue des Martyrs, F-30854, Grenoble Cedex 9, France — ³Institute of Physics and Astronomy, University of Aarhus, DK-8000 Århus C, Denmark — ⁴Manne Siegbahn Laboratory, Frescativägen 24, S-104 05 Stockholm, Sweden

The main theme of the present discussion is how various collision experiments may be used to study the electronic response of the C₆₀ molecule. Since the discovery of C₆₀ and the method for its mass production, the molecular properties have been investigated by means of its exposure to photons, electrons, clusters (neutral or charged), and atomic ions of varying charge states and velocities. Issues of particular interest here are the ones about energy transfer (heating), cold electron capture, ionization and fragmentation, and strong electron emission in interactions with slow highly charged ions. A new generalized model for electron transfer between two conducting spheres of arbitrary radii [1] is used as a basis for the discussion of recent experimental results on slow C₆₀^q+–C₆₀ [2,3], C^q+–C₆₀ [2], Ar^q+–C₆₀ [4], Xe³⁰⁺–C₆₀, and Pb⁵⁴⁺–C₆₀ collisions. The difference in the C₆₀ target charge–state distributions for atomic– and C₆₀^q+–projectile ions is reproduced by selecting model projectile radii to be very small or equal to the C₆₀ radius (7.2 a₀), respectively. Further, this model shows that electrons will be captured to excited states of C₆₀²⁺ in C₆₀⁴⁺-C₆₀ collisions offering a possible explanation for the observed higher tendency for the projectile– than for the target–C₆₀²⁺ to fragment after two–electron transfer [3].

We discuss the formation of hollow atomic projectiles, which according to the model is completed a few atomic units from the C₆₀–cage surface. Ultra–fast emission of highly excited electrons from the outer projectile shells may thus occur in shake–off like processes as vacant intermediate projectile shells are filled making the net projectile charge negative [4]. We note that this mechanism offers a way to rationalize the observation of strong electron emission [5] during the very short interaction (typically sub–femtosecond) between highly charged ions and C₆₀. We will also discuss experimental evidence for very efficient target carbon K–shell vacancy production in collisions between sufficiently highly charged atomic ions and C₆₀ [4]. Finally we give a very brief progress report from ongoing investigations of the stability of highly charged C₆₀^q+.

[1] H. Zettergren, H. Schmidt, S. Tomita, P. Hvelplund, H. Lebius, B. Huber, and H. Cederquist, ECAMP VII postersession (2001).

[2] H. Cederquist, P. Hvelplund, H. Lebius, H.T. Schmidt, S. Tomita, and B.A. Huber, Phys. Rev. A 63 (2001).

[3] H. Lebius, H. Schmidt, S. Tomita, P. Hvelplund, H. Cederquist, and B.A. Huber, Phys. Rev. A to be submitted (2001).

[4] A. Langereis, J. Jensen, A. Fardi, K. Haghighat, H.T. Schmidt, S.H. Schwartz, H. Zettergren, and H. Cederquist, Phys. Rev. A submitted (2001).

[5] S. Martin, L. Chen, A. Denis, and J. Désesquelles, Phys. Rev. A 59, 1734 (1999).