Abstract
In our previous publications, we introduced a concept of complex bend, which is a bending element consisting of dipole poles, interleaved with strong focusing and defocusing quadrupole poles. An electron ring built from such elements features low emittance while preserving substantial room for insertion devices and associated lattice elements. In this paper, we present two new optics solutions for the complex bend which offer to substantially reduce the device length by removing the dipole poles. In the first of the solutions, the bending is realized by shifting the quadrupole poles along the curved horizontal axis. For the second solution, we use permanent magnet quadrupole poles installed into a wide gap of the conventional electromagnet. In this case, the resulting bending field in the magnet gap is a superposition of the quadrupole field from the poles and the dipole field from the conventional magnet. We present an analysis of the particle motion and synchrotron radiation emitted in such fields, as well as an assessment of the ring linear lattice that is composed of complex bend elements.
Highlights
We introduced a concept of complex bend, which is a bending element consisting of dipole poles, interleaved with strong focusing and defocusing quadrupole poles
We present an analysis of the particle motion and synchrotron radiation emitted in such fields, as well as an assessment of the ring linear lattice that is composed of complex bend elements
In Refs. [1,2], we reported the conceptual details of a complex bend element, which is based on a sequence of strong focusing poles of alternating polarity, interleaved with pure dipole poles, providing bending
Summary
In Refs. [1,2], we reported the conceptual details of a complex bend element, which is based on a sequence of strong focusing poles of alternating polarity, interleaved with pure dipole poles, providing bending. [3], we have considered a modification of the complex bend element, aiming to reduce its overall length, lower the quadrupole strength, and, free up more space in the storage ring lattice available for installing lattice magnets, diagnostics, and insertion devices. We realized this modification by removing dipole poles from the element and enabling the bending either by quadrupole poles, shifted transversely, or by an external field introduced by an electromagnet with the quadrupole poles fitted inside its gap.
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