Algebraic cluster models calculations for shape phase transitions of boson-fermion systems

M.A.Jafarizadeh; M.Ghapanvari; N.Amiri

arxiv: 1907.08999 · v1 · pith:DNB7CR45new · submitted 2019-07-21 · ⚛️ nucl-th

Algebraic cluster models calculations for shape phase transitions of boson-fermion systems

M.Ghapanvari , N.Amiri , M.A.Jafarizadeh This is my paper

Pith reviewed 2026-05-24 18:16 UTC · model grok-4.3

classification ⚛️ nucl-th

keywords algebraic cluster modelshape phase transitionsaffine SU(1,1) Lie algebraboson-fermion systemstransitional Hamiltoniannuclear cluster configurationsO(4) U(3) transition

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The pith

An extended transitional Hamiltonian from affine SU(1,1) Lie algebra solves shape phase transitions in algebraic cluster models for boson-fermion systems.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper constructs a solvable Hamiltonian using affine SU(1,1) Lie algebra for two-, three-, and four-body algebraic cluster models. This Hamiltonian accounts for the phase transitions between O(4) and U(3), O(7) and U(6), and O(10) and U(9) symmetries. It enables calculations of energy levels and wave functions for specific nuclear structures like those in 9Be, 13C, and 17O, including the coupling of an odd nucleon to a boson core. Sympathetic readers would care because it offers an exact solvable framework for studying shape changes in light nuclei without losing analytic control.

Core claim

We schemed a solvable extended transitional Hamiltonian based on affine SU(1,1) Lie algebra within the framework for two-, three- and four- body algebraic cluster models that explains both regions O(4)↔U(3), O(7)↔U(6) and O(10)↔U(9), respectively. Numerical extraction to the energy levels, the expectation value of boson number operator and behavior of the overlap of the ground-state wave function within the control parameters of this evaluated Hamiltonian are presented. The effect of the coupling of the odd particle to an even-even boson core is discussed along the shape transition and, in particular, at the critical point.

What carries the argument

The affine SU(1,1) Lie algebra extended transitional Hamiltonian, which generates exact solutions for the vibrational and rotational degrees of freedom in cluster configurations.

Load-bearing premise

The affine SU(1,1) Lie algebra supplies a Hamiltonian whose eigenvalues and eigenstates directly correspond to physical energy levels and wave functions of the cluster configurations without requiring additional approximations that break solvability.

What would settle it

Experimental measurement of energy levels in nuclei such as 9Be or 13C that deviate significantly from the predictions of this Hamiltonian would falsify the model's applicability.

Figures

Figures reproduced from arXiv: 1907.08999 by M.A.Jafarizadeh, M.Ghapanvari, N.Amiri.

**Figure 2.** Figure 2: FIG. 2. Energy levels as a function of the control parameter C [PITH_FULL_IMAGE:figures/full_fig_p018_2.png] view at source ↗

**Figure 3.** Figure 3: FIG. 3. Energy levels as a function of the control parameter C [PITH_FULL_IMAGE:figures/full_fig_p018_3.png] view at source ↗

**Figure 4.** Figure 4: FIG. 4. The root mean square deviation as a function of the con [PITH_FULL_IMAGE:figures/full_fig_p019_4.png] view at source ↗

**Figure 5.** Figure 5: FIG. 5. The root mean square deviation as a function of the con [PITH_FULL_IMAGE:figures/full_fig_p020_5.png] view at source ↗

**Figure 6.** Figure 6: FIG. 6. The root mean square deviation as a function of the con [PITH_FULL_IMAGE:figures/full_fig_p020_6.png] view at source ↗

**Figure 7.** Figure 7: FIG. 7. The expectation values of the vector-boson number op [PITH_FULL_IMAGE:figures/full_fig_p021_7.png] view at source ↗

**Figure 8.** Figure 8: FIG. 8. The Calculated variation behavior of the overlap of t [PITH_FULL_IMAGE:figures/full_fig_p021_8.png] view at source ↗

read the original abstract

The Algebraic Cluster Model(ACM) is an interacting boson model that gives the relative motion of the cluster configurations in which all vibrational and rotational degrees of freedom are present from the outset. We schemed a solvable extended transitional Hamiltonian based on affine $ {{SU(1,1)}} $ Lie algebra within the framework for two-, three- and four- body algebraic cluster models that explains both regions $ O(4)\leftrightarrow U(3) $, $ O(7)\leftrightarrow U(6) $ and $ O(10)\leftrightarrow U(9) $, respectively . We offer that this method can be used to study of $k\alpha + x$ nucleon structures with k = 2, 3,4 and x = 1, 2, . . . , in specific x = 1,2 such as structures $^{9}Be$,$^{9}B$,$^{10}B$ ; $^{13}C$, $^{13}N$, $^{14}N$; $^{17}O$, $^{17}F$. Numerical extraction to the energy levels, the expectation value of boson number operator and behavior of the overlap of the ground-state wave function within the control parameters of this evaluated Hamiltonian are presented. The effect of the coupling of the odd particle to an even-even boson core is discussed along the shape transition and, in particular, at the critical point.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper builds transitional Hamiltonians with affine SU(1,1) for ACM boson-fermion systems across three O(n)-U(m) regions and shows numerical behavior for a few light nuclei, but the derivations and external checks are thin.

read the letter

The main point is that the authors construct an extended solvable Hamiltonian using affine SU(1,1) inside the algebraic cluster model framework, now including the odd-particle coupling, and they apply it to the O(4)↔U(3), O(7)↔U(6), and O(10)↔U(9) transitions for two-, three-, and four-body clusters. They target specific light nuclei such as 9Be, 13C, and 17O and extract energy levels, boson-number expectations, and ground-state overlaps while varying the control parameters. They also note how the odd nucleon affects the transition, especially near the critical point. This is a direct technical step beyond earlier ACM work on even systems. The numerical illustrations of how spectra and overlaps change through the transition are the clearest part of the contribution. The algebra is presented as furnishing closed-form results for the full Hamiltonian, which is the central claim. The soft spots are straightforward. The abstract gives no derivation steps or explicit checks that the fermion coupling preserves exact solvability at arbitrary control-parameter values, so it is not possible to confirm the claim without the full algebra. The results are generated by varying the control parameters to trace the transition, with no reported comparison to measured spectra or independent benchmarks, so the outputs remain inside the model. No error estimates appear. These are real limitations for anyone who wants to treat the numbers as predictions rather than illustrations. The work sits squarely inside algebraic nuclear-structure theory. A reader who already works with the interacting boson model, cluster models, or Lie-algebra techniques in light nuclei will see the concrete construction and the plotted behavior. It will not move broader nuclear physics. The paper deserves a serious referee to verify the algebra and to ask for direct data comparisons or at least a clear statement of where the solvability stops. I would send it to review rather than desk-reject.

Referee Report

2 major / 1 minor

Summary. The manuscript proposes a solvable extended transitional Hamiltonian constructed from affine SU(1,1) Lie algebra within the algebraic cluster model framework for two-, three-, and four-body systems. It claims this Hamiltonian describes the shape-phase transitions O(4)↔U(3), O(7)↔U(6), and O(10)↔U(9), incorporates odd-particle (fermion) coupling, and is applied to nuclei such as 9Be, 13C, 17O. Numerical results are presented for energy levels, expectation values of the boson number operator, and ground-state wave-function overlaps as functions of the control parameters, with discussion of the critical-point behavior under boson-fermion coupling.

Significance. If the exact solvability of the full Hamiltonian (including the boson-fermion interaction term) is rigorously demonstrated with closed-form eigenvalues and eigenstates, the approach would supply a controlled algebraic framework for tracing shape transitions in light cluster nuclei that include both even-even and odd-A systems. The numerical extraction of overlaps and boson-number expectation values could then serve as falsifiable signatures for experimental tests in the cited nuclei.

major comments (2)

[Abstract] Abstract: the claim that the Hamiltonian is exactly solvable for arbitrary values of the control parameters is stated without any derivation of the eigenvalues or eigenstates of the full boson-fermion Hamiltonian; this derivation is load-bearing for all subsequent numerical results and must be supplied explicitly (including the form of the affine SU(1,1) generators and the boson-fermion coupling term).
The manuscript supplies no error estimates on the numerical spectra, no direct comparison of calculated levels with experimental data for the cited nuclei (9Be, 13C, etc.), and no independent benchmark (e.g., limiting cases or known solvable points) that would confirm the overlaps and boson-number values are genuine predictions rather than fits.

minor comments (1)

Notation for the control parameters and the precise definition of the affine SU(1,1) generators should be introduced with explicit equations before the numerical sections.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We appreciate the referee's detailed review and suggestions for improving the manuscript. We address each major comment below and plan to incorporate revisions to strengthen the presentation of the solvability and numerical aspects.

read point-by-point responses

Referee: [Abstract] Abstract: the claim that the Hamiltonian is exactly solvable for arbitrary values of the control parameters is stated without any derivation of the eigenvalues or eigenstates of the full boson-fermion Hamiltonian; this derivation is load-bearing for all subsequent numerical results and must be supplied explicitly (including the form of the affine SU(1,1) generators and the boson-fermion coupling term).

Authors: The construction of the extended transitional Hamiltonian is based on the affine SU(1,1) Lie algebra, and the manuscript provides the form of the Hamiltonian and its application. However, to address this valid point, we will expand the manuscript with an explicit derivation of the eigenvalues and eigenstates for the full boson-fermion system, including the definitions of the generators and the coupling term. This will be added in a new subsection to rigorously support the numerical results. revision: yes
Referee: The manuscript supplies no error estimates on the numerical spectra, no direct comparison of calculated levels with experimental data for the cited nuclei (9Be, 13C, etc.), and no independent benchmark (e.g., limiting cases or known solvable points) that would confirm the overlaps and boson-number values are genuine predictions rather than fits.

Authors: We note that the focus of the paper is on the development of the algebraic model and the qualitative behavior of the shape phase transitions, including the effect of the odd particle coupling, rather than quantitative fits to data. Nevertheless, we agree that providing benchmarks would enhance credibility. In the revised manuscript, we will include calculations in the limiting cases (pure dynamical symmetries) as independent checks, and add error estimates for the numerical diagonalization where relevant. Direct comparisons with experimental data for the specific nuclei are not included as the work is primarily methodological, but the model parameters can be adjusted for such comparisons in future studies. revision: partial

Circularity Check

0 steps flagged

No significant circularity

full rationale

The paper constructs an extended transitional Hamiltonian from the affine SU(1,1) Lie algebra for the two-, three-, and four-body cluster models and then extracts numerical spectra, boson-number expectations, and ground-state overlaps by varying the control parameters. No quoted equation or self-citation reduces a claimed prediction or eigenvalue to a fitted input by construction; the algebraic framework supplies the closed-form solvability directly, and the reported quantities follow from that construction without the load-bearing steps matching any of the enumerated circularity patterns.

Axiom & Free-Parameter Ledger

1 free parameters · 1 axioms · 0 invented entities

The central construction rests on the standard assumption that affine SU(1,1) supplies a solvable basis for the transitional Hamiltonian; no new entities are introduced.

free parameters (1)

control parameters of the Hamiltonian
Varied to move between symmetry limits and to extract numerical spectra and overlaps.

axioms (1)

domain assumption Affine SU(1,1) Lie algebra yields an exactly solvable extended transitional Hamiltonian for the stated O(n)-U(m) pairs.
Invoked to guarantee solvability of the model for two-, three-, and four-body systems.

pith-pipeline@v0.9.0 · 5786 in / 1302 out tokens · 21877 ms · 2026-05-24T18:16:26.936402+00:00 · methodology

discussion (0)

Reference graph

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[1] [1]

The 9 4Be nucleus , which has unlimited system properties 2 α + n is the cornerstone of cluster physics[18, 21, 22, 32]

The odd-A nuclei : 9 4Be and 9 4B For more than two decades, is known that the 9 4Be nucleus is an example of a molecular covalent bond in nuclear physics, Where two particles with valence neutron are limited. The 9 4Be nucleus , which has unlimited system properties 2 α + n is the cornerstone of cluster physics[18, 21, 22, 32]. Due to its low n eutron se...

work page

[2] [2]

In this paper, the method described in Refs.[38, 39 ] will be developed and performed to mixed boson-fermion-fermion systems

The odd-odd nuclei : 10 5 B The structure of the odd-odd nuclei may be illustrated as an unpair ed proton and an unpaired neutron coupled to a boson core. In this paper, the method described in Refs.[38, 39 ] will be developed and performed to mixed boson-fermion-fermion systems. The approach based on boson- fermion symmetries has been also applied to odd...

work page

[3] [3]

To start we can regard to the properties of 13C for which the experimental evidence has recently been collected [18, 31, 32]

The odd-A nuclei : 13 6 C and 13 7 N Similar to the covalently bound structures of two α particles and neutrons discussed earlier, we can continue the discussion with three α particles and neutrons. To start we can regard to the properties of 13C for which the experimental evidence has recently been collected [18, 31, 32]. The structure of the linear chai...

work page

[4] [4]

The study of 14N nuclei can expand understanding of the evolution of increasingly co mplex structures beyond the α -clustering

The odd-odd nuclei : 14 7 N The 14N nucleus is considered as a mediator between the cluster nucleus 12C and the doubly magic nucleus 16O [17, 32]. The study of 14N nuclei can expand understanding of the evolution of increasingly co mplex structures beyond the α -clustering. The information about the structure of 14N has practical value. As a major compone...

work page

[5] [5]

The negative parity states in the even - odd nuclei 17 8 O and 17 9 F are built mainly on the 1p 1 2 shell model orbit

The odd-A nuclei : 17 8 O and 17 9 F In this work, we study the structure 17 8 O as Four - α particles and a neutron and 17 9 F as Four - α particles and a proton. The negative parity states in the even - odd nuclei 17 8 O and 17 9 F are built mainly on the 1p 1 2 shell model orbit. The single - particle orbits 1d 5 2 and 2s 1 2 establish the positive par...

work page

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Iachello, F., Iachello, F., Arima, A., and Iachello, F. ( 1987). The interacting boson model. Cambridge University P ress

work page 1987

[7] [7]

Iachello, F., and Levine, R. D. (1995). Algebraic theory of molecules. Oxford University Press

work page 1995

[8] [8]

Bijker, R. (2012). Spectrum generating algebras for few -body systems. In Journal of Physics: Conference Series (Vo l. 380, No. 1, p. 012003). IOP Publishing

work page 2012

[9] [9]

Bijker, R., and Iachello, F. (2017). The algebraic clust er model: Structure of 16O. Nuclear Physics A, 957, 154-176

work page 2017

[10] [10]

Bijker, R., and Iachello, F. (2000). Cluster states in nu clei as representations of a U (ν + 1) group. Physical Review C, 61(6), 067305

work page 2000

[11] [11]

Bijker, R., and Iachello, F. (2002). The algebraic clust er model: Three-body clusters. Annals of Physics, 298(2), 3 34-360

work page 2002

[12] [12]

Iachello, F., and Jackson, A. D. (1982). A phenomenologi cal approch to α-clustering in heavy nuclei. Physics Letters B, 108(3), 151-154

work page 1982

[13] [13]

Iachello, F. (1983). Algebraic approach to nuclear stru cture. Nuclear Physics A, 396, 233-243. 11

work page 1983

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Daley, H., and Iachello, F. (1983). Alpha-clustering in heavy nuclei. Physics Letters B, 131(4-6), 281-284

work page 1983

[15] [15]

C., and Zhang, L

Iachello, F., Mukhopadhyay, N. C., and Zhang, L. (1991) . Spectrum-generating algebra for stringlike mesons: Mass formula for q ¯q mesons. Physical Review D, 44(3), 898

work page 1991

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Iachello, F., and Kusnezov, D. (1992). Radiative decay s of ( Q ¯Q) mesons. Physical Review D, 45(11), 4156

work page 1992

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Bijker, R., Iachello, F., and Leviatan, A. (1994). Alge braic models of hadron structure. I. Nonstrange baryons. An nals of Physics, 236(1), 69-116

work page 1994

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Bijker, R., Iachello, F., and Leviatan, A. (2000). Alge braic models of hadron structure: II. Strange baryons. Anna ls of Physics, 284(1), 89-133

work page 2000

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