Quantum chaos, localized states and clustering in excited spectra of Jahn–Teller models

Abstract: We studied complex spectra of spin-two boson systems represented by E⊗e and E⊗(b1 +b2) Jahn-Teller models. For E⊗e, at particular rotation quantum numbers we found a coexistence of up to three regions of the spectra, (i) the dimerized region of long-range ordered (extended) pairs of oscillating levels, (ii) the short-range ordered (localized) "kink lattice" of avoiding levels, and (iii) the intermediate region of kink nucleation with variable range of ordering. This structure appears above certain critical lin… Show more

“…33) Actually, apart from the rattling problem, the appearance of chaos in the vibronic state, i.e., the complicated electronvibration coupled state, has been already pointed out by several groups. [34][35][36][37][38][39][40] However, we hit upon an idea that chaos originates from anharmonic Jahn-Teller vibration, not from the vibronic state composed of electron and anharmonic Jahn-Teller vibration. It is important to confirm that the origin of chaos exists in the anharmonic Jahn-Teller oscillator, since it will provide us a realistic model in condensed-matter physics for the research of chaos in nonlinear physics.…”

Chaos in Jahn–Teller Rattling

“…33) Actually, apart from the rattling problem, the appearance of chaos in the vibronic state, i.e., the complicated electronvibration coupled state, has been already pointed out by several groups. [34][35][36][37][38][39][40] However, we hit upon an idea that chaos originates from anharmonic Jahn-Teller vibration, not from the vibronic state composed of electron and anharmonic Jahn-Teller vibration. It is important to confirm that the origin of chaos exists in the anharmonic Jahn-Teller oscillator, since it will provide us a realistic model in condensed-matter physics for the research of chaos in nonlinear physics.…”

Chaos in Jahn–Teller Rattling