News articles

Stop! In the Name of Carbon

A bullet fired through a block of wood will slow down. In a similar way, ions are decelerated when they pass through a solid material: the thicker the material, the larger the energy loss will be. However, this picture breaks down in ultra-thin target materials, which only consist of a few layers of atoms.

[Translate to English:]

1 of 5 images or videos

[Translate to English:]

[Translate to English:]

[Translate to English:] Manche Ionen gelangen auf geradem Weg durch die Folie, andere erfahren heftigere Ablenkungen.

1 of 5 images or videos

[Translate to English:] Manche Ionen gelangen auf geradem Weg durch die Folie, andere erfahren heftigere Ablenkungen.

[Translate to English:] Manche Ionen gelangen auf geradem Weg durch die Folie, andere erfahren heftigere Ablenkungen.

[Translate to English:]

1 of 5 images or videos

[Translate to English:]

[Translate to English:]

[Translate to English:]

1 of 5 images or videos

[Translate to English:]

[Translate to English:]

[Translate to English:] Prof. Friedrich Aumayr

1 of 5 images or videos

[Translate to English:] Prof. Friedrich Aumayr

[Translate to English:] Prof. Friedrich Aumayr

Passing through a carbon membrane, highly charged ions can lose energy and change their charge state. If the case of extremely thin nano-membranes, however, two very distinct charge distributions are visible. They can be attributed to two different electron capture scenarios. Close collisions of the incident ion with target atoms can change the charge state dramatically and lead almost to neutralization, accompanied by considerable energy loss. If the ion, on the other hand, passes the target atoms at larger distances, it only captures a small number of electrons and hardly loses any energy. Therefore, the energy deposition by an ion in extremely thin materials cannot be expressed in terms of an average energy loss per ion path length.

These experiments show for the first time that the energy loss is strongly dependent on the charge state of the incident ion. Usually, this effect is not visible: in thicker films, the ions quickly reach an equilibrium charge state, independent of their original charge.

Understanding the energy and charge transfer of ions passing through membranes is a vital prerequisite for developing surface nanostructuring techniques by slow highly charged ions. The localized energy deposition in inelastic collisions with the target atoms makes it possible to engineer molecular sieves in a very simple and efficient way.

<link http: journals.aps.org prl abstract physrevlett.112.153201 link_extern>Original Publication

<link http: www.tuwien.ac.at dle pr aktuelles downloads karbonfolie link_extern>Bilderdownload

Further Information:
Univ.Prof. Friedrich Aumayr
Institute for Applied Physics
Vienna University of Technology
Wiedner Hauptstraße 8-10, 1040 Vienna
T: +43-1-58801-134 30
<link>friedrich.aumayr@tuwien.ac.at