Birmingham Academic honoured with Extreme Mechanics Letters Young Investigator Award

 The Young Investigator Award (YIA) from Extreme Mechanics Letters (EML) honours the best young researchers who have published highly impactful papers in EML.

EML publishes rapid communication of research that highlights the role of mechanics in multi-disciplinary areas across materials science, physics, chemistry, biology, medicine and engineering. Emphasis is on the impact, depth and originality of new concepts, methods and observations at the forefront of applied sciences.

The YIA is awarded annually to the paper's corresponding authors who received their PhD no more than ten years before the award year.

This year, seven young researchers received nominations from documents published in EML in Volumes 57-62 from 2022 to 2023; two were eventually named the winners, including Dr Mingchao Liu, Assistant Professor at the University of Birmingham and Evgueni T. Filipov, Associate Professor, University of Michigan, USA.

Dr Liu was selected based on his two papers, "Modeling of magnetic cilia carpet robots using discrete differential geometry formulation", Extreme Mechanics Letters, Volume 59, P. 101967 (2023) and "A discrete model for the geometrically nonlinear mechanics of hard-magnetic slender structures", Extreme Mechanics Letters, Volume 59, P. 101977 (2023).

In the first, Dr Liu and collaborators developed a discrete magneto-elastic rod model for simulating the dynamic behaviours of hard-magnetic slender structures, notable for its high computational efficiency and applicability to complex micro-structures in varied environments, particularly in soft robotics.

The second paper extends this model to the dynamic analysis of bio-inspired cilia carpet robots driven by external magnetic fields. This framework is crucial for understanding microorganism biophysics and provides guidelines for designing bio-inspired soft robots for biomedical applications.

Dr Liu's research focuses on the mechanics of slender structures and their applications in modelling and designing robotic metamaterials with innovative functions, which include programmable robotic behaviours such as shape-morphing, multimodal locomotion, mechanical sensing, actuation, and memory, as well as tunable mechanical properties.

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Bending Reality: Einstein Meets Quantum Mechanics in Antarctic Ice

GravityIceCube Neutrino ObservatoryNeutrinosParticle PhysicsPopularQuantum GravityQuantum MechanicsQuantum PhysicsUniversity Of Texas At Arlington

By KATHERINE EGAN BENNETT, UNIVERSITY OF TEXAS AT ARLINGTON

Experimental Efforts in Antarctica

“The challenge of unifying quantum mechanics with the theory of gravitation remains one of the most pressing unsolved problems in physics,” said co-author Benjamin Jones, associate professor of physics. “If the gravitational field behaves in a similar way to the other fields in nature, its curvature should exhibit random quantum fluctuations.”

Jones and UTA graduate students Akshima Negi and Grant Parker were part of an international IceCube Collaboration team that included more than 300 scientists from around the U.S., as well as Australia, Belgium, Canada, Denmark, Germany, Italy, Japan, New Zealand, Korea, Sweden, Switzerland, Taiwan and the United Kingdom.

To search for signatures of quantum gravity, the team placed thousands of sensors throughout one square kilometer near the south pole in Antarctica that monitored neutrinos, unusual but abundant subatomic particles that are neutral in charge and have no mass. The team was able to study more than 300,000 neutrinos. They were looking to see whether these ultra-high-energy particles were bothered by random quantum fluctuations in spacetime that would be expected if gravity were quantum mechanical, as they travel long distances across the Earth.
Results of Neutrino Observations

“We searched for those fluctuations by studying the flavors of neutrinos detected by the IceCube Observatory,” Negi said. “Our work resulted in a measurement that was far more sensitive than previous ones (over a million times more, for some of the models), but it did not find evidence of the expected quantum gravitational effects.”

This non-observation of a quantum geometry of spacetime is a powerful statement about the still-unknown physics that operate at the interface of quantum physics and general relativity.

“This analysis represents the final chapter in UTA’s nearly decade-long contribution to the IceCube Observatory,” said Jones. “My group is now pursuing new experiments that aim to understand the origin and value of the neutrinos mass using atomic, molecular, and optical physics techniques.”


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Bending Reality: Einstein Meets Quantum Mechanics in Antarctic Ice

TOPICS: Gravity Ice Cube Neutrino Observatory Neutrinos Particle Physics Popular Quantum Gravity Quantum Mechanics Quantum Physics University Of Texas At Arlington

By KATHERINE EGAN BENNETT, UNIVERSITY OF TEXAS AT ARLINGTON

Research at the South Pole studied the mysterious quantum structure of space and time.

Einstein’s theory of general relativity explains that gravity is caused by a curvature of the directions of space and time. The most familiar manifestation of this is the Earth’s gravity, which keeps us on the ground and explains why balls fall to the floor and individuals have weight when stepping on a scale.

In the field of high-energy physics, on the other hand, scientists study tiny invisible objects that obey the laws of quantum mechanics—characterized by random fluctuations that create uncertainty in the positions and energies of particles like electrons, protons, and neutrons. Understanding the randomness of quantum mechanics is required to explain the behavior of matter and light on a subatomic scale.

Pursuit of Quantum Gravity

For decades, scientists have been trying to unite those two fields of study to achieve a quantum description of gravity. This would combine the physics of curvature associated with general relativity with the mysterious random fluctuations associated with quantum mechanics.

A new study in Nature Physics from physicists at The University of Texas at Arlington reports on a deep new probe into the interface between these two theories, using ultra-high energy neutrino particles detected by a particle detector set deep into the Antarctic glacier at the south pole.

Experimental Efforts in Antarctica

“The challenge of unifying quantum mechanics with the theory of gravitation remains one of the most pressing unsolved problems in physics,” said co-author Benjamin Jones, associate professor of physics. “If the gravitational field behaves in a similar way to the other fields in nature, its curvature should exhibit random quantum fluctuations.”

Jones and UTA graduate students Akshima Negi and Grant Parker were part of an international IceCube Collaboration team that included more than 300 scientists from around the U.S., as well as Australia, Belgium, Canada, Denmark, Germany, Italy, Japan, New Zealand, Korea, Sweden, Switzerland, Taiwan and the United Kingdom.

To search for signatures of quantum gravity, the team placed thousands of sensors throughout one square kilometer near the south pole in Antarctica that monitored neutrinos, unusual but abundant subatomic particles that are neutral in charge and have no mass. The team was able to study more than 300,000 neutrinos. They were looking to see whether these ultra-high-energy particles were bothered by random quantum fluctuations in spacetime that would be expected if gravity were quantum mechanical, as they travel long distances across the Earth.



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New theory unites Einstein’s gravity with quantum mechanics

A radical theory that consistently unifies gravity and quantum mechanics while preserving Einstein’s classical concept of spacetime is announced today in two papers published simultaneously by UCL physicists 

A radical theory that consistently unifies gravity and quantum mechanics while preserving Einstein’s classical concept of spacetime is announced today in two papers published simultaneously by UCL (University College London) physicists.

Modern physics is founded upon two pillars: quantum theory on the one hand, which governs the smallest particles in the universe, and Einstein’s theory of general relativity on the other, which explains gravity through the bending of spacetime. But these two theories are in contradiction with each other and a reconciliation has remained elusive for over a century.

The prevailing assumption has been that Einstein’s theory of gravity must be modified, or “quantised”, in order to fit within quantum theory. This is the approach of two leading candidates for a quantum theory of gravity, string theory and loop quantum gravity.

But a new theory, developed by Professor Jonathan Oppenheim (UCL Physics & Astronomy) and laid out in a new paper in Physical Review X (PRX), challenges that consensus and takes an alternative approach by suggesting that spacetime may be classical – that is, not governed by quantum theory at all.

Instead of modifying spacetime, the theory - dubbed a “postquantum theory of classical gravity” - modifies quantum theory and predicts an intrinsic breakdown in predictability that is mediated by spacetime itself. This results in random and violent fluctuations in spacetime that are larger than envisaged under quantum theory, rendering the apparent weight of objects unpredictable if measured precisely enough.

A second paper, published simultaneously in Nature Communications and led by Professor Oppenheim’s former PhD students, looks at some of the consequences of the theory, and proposes an experiment to test it: to measure a mass very precisely to see if its weight appears to fluctuate over time.

For example, the International Bureau of Weights and Measures in France routinely weigh a 1kg mass which used to be the 1kg standard. If the fluctuations in measurements of this 1kg mass are smaller than required for mathematical consistency, the theory can be ruled out.

The outcome of the experiment, or other evidence emerging which would confirm the quantum vs classical nature of spacetime, is the subject of a 5000:1 odds bet between Professor Oppenheim and Professor Carlo Rovelli and Dr Geoff Penington – leading proponents of quantum loop gravity and string theory respectively.

For the past five years, the UCL research group has been stress-testing the theory, and exploring its consequences.

Professor Oppenheim said: "Quantum theory and Einstein's theory of general relativity are mathematically incompatible with each other, so it's important to understand how this contradiction is resolved. Should spacetime be quantised, or should we modify quantum theory, or is it something else entirely? Now that we have a consistent fundamental theory in which spacetime does not get quantised, it’s anybody’s guess.”

Co-author Zach Weller-Davies, who as a PhD student at UCL helped develop the experimental proposal and made key contributions to the theory itself, said: "This discovery challenges our understanding of the fundamental nature of gravity but also offers avenues to probe its potential quantum nature.

“We have shown that if spacetime doesn’t have a quantum nature, then there must be random fluctuations in the curvature of spacetime which have a particular signature that can be verified experimentally.

“In both quantum gravity and classical gravity, spacetime must be undergoing violent and random fluctuations all around us, but on a scale which we haven’t yet been able to detect. But if spacetime is classical, the fluctuations have to be larger than a certain scale, and this scale can be determined by another experiment where we test how long we can put a heavy atom in superposition* of being in two different locations."

Co-authors Dr Carlo Sparaciari and Dr Barbara Šoda, whose analytical and numerical calculations helped guide the project, expressed hope that these experiments could determine whether the pursuit of a quantum theory of gravity is the right approach.

Dr Šoda (formerly UCL Physics & Astronomy, now at the Perimeter Institute of Theoretical Physics, Canada) said: “Because gravity is made manifest through the bending of space and time, we can think of the question in terms of whether the rate at which time flows has a quantum nature, or classical nature.

“And testing this is almost as simple as testing whether the weight of a mass is constant, or appears to fluctuate in a particular way.”

Dr Sparaciari (UCL Physics & Astronomy) said: “While the experimental concept is simple, the weighing of the object needs to be carried out with extreme precision.

“But what I find exciting is that starting from very general assumptions, we can prove a clear relationship between two measurable quantities – the scale of the spacetime fluctuations, and how long objects like atoms or apples can be put in quantum superposition of two different locations. We can then determine these two quantities experimentally.”

Weller-Davies added: “A delicate interplay must exist if quantum particles such as atoms are able to bend classical spacetime. There must be a fundamental trade-off between the wave nature of atoms, and how large the random fluctuations in spacetime need to be.”

The proposal to test whether spacetime is classical by looking for random fluctuations in mass is complementary to another experimental proposal which aims to verify the quantum nature of spacetime by looking for something called “gravitationally mediated entanglement.”

Professor Sougato Bose (UCL Physics & Astronomy), who was not involved with the announcement today, but was among those to first propose the entanglement experiment, said: “Experiments to test the nature of spacetime will take a large-scale effort, but they're of huge importance from the perspective of understanding the fundamental laws of nature. I believe these experiments are within reach – these things are difficult to predict, but perhaps we'll know the answer within the next 20 years.”

The postquantum theory has implications beyond gravity. The infamous and problematic “measurement postulate” of quantum theory is not needed, since quantum superpositions necessarily localise through their interaction with classical spacetime.

The theory was motivated by Professor Oppenheim’s attempt to resolve the black hole information problem. According to standard quantum theory, an object going into a black hole should be radiated back out in some way as information cannot be destroyed, but this violates general relativity, which says you can never know about objects that cross the black hole’s event horizon. The new theory allows for information to be destroyed, due to a fundamental breakdown in predictability.

* Background information

Quantum mechanics background: All the matter in the universe obeys the laws of quantum theory, but we only really observe quantum behaviour at the scale of atoms and molecules. Quantum theory tells us that particles obey Heisenberg’s uncertainty principle, and we can never know their position or velocity at the same time. In fact, they don’t even have a definite position or velocity until we measure them. Particles like electrons can behave more like waves and act almost as if they can be in many places at once (more precisely, physicists describe particles as being in a “superposition” of different locations).

Quantum theory governs everything from semiconductors which are ubiquitous in computer chips, to lasers, to superconductivity to radioactive decay. In contrast, we say that a system behaves classically if it has definite underlying properties. A cat appears to behave classically – it is either dead or alive, not both, nor in a superposition of being dead and alive. Why do cats behave classically, and small particles quantumly? We don’t know, but the postquantum theory doesn’t require the measurement postulate, because the classicality of spacetime infects quantum systems and causes them to localise.

Gravity background: Newton’s theory of gravity, gave way to Einstein’s theory of general relativity (GR), which holds that gravity is not a force in the usual sense. Instead, heavy objects such as the sun, bend the fabric of spacetime in such a way that causes the earth to revolve around it. Spacetime is just a mathematical object consisting of the three dimensions of space, and time considered as a fourth dimension. General relativity predicted the formation of black holes and the big bang. It holds that time flows at different rates at different points in space, and the GPS in your smartphone needs to account for this in order to properly determine your location.

Historical context: The framework presented by Oppenheim in PRX, and in a companion paper with Sparaciari, Šoda and Weller-Davies, derives the most general consistent form of dynamics in which a quantum system interacts with a classical system. It then applies this framework to the case of general relativity coupled to quantum fields theory. It builds on earlier work and a community of physicists. An experiment to test the quantum nature of gravity via gravitationally mediated entanglement was proposed by Bose et. al. and by C. Marletto and V. Vadral. Two examples of consistent classical-quantum dynamics were discovered in the 90’s by Ph. Blanchard and A. Jadzyk, and by Lajos Diosi, and again by David Poulin around 2017. From a different perspective, in 2014 a model of Newtonian gravity coupled to quantum systems via a “measurement-and-feedback” approach, was presented by Diosi and Antoinne Tilloy in 2016, and by D Kafri, J. Taylor, and G. Milburn, in 2014. The idea that gravity might be somehow related to the collapse of the wavefunction, dates back to F. Karolyhazy (1966), L. Diosi (1987) and R. Penrose (1996). That classical-quantum couplings might explain localistation of the wavefunction has been suggested by others including M. Hall and M. Reginatto, Diosi and Tilloy, and David Poulin. The idea that spacetime might be classical dates back to I. Sato (1950), and C. Moller (1962), but no consistent theory was found until now.

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Unveiling Quantum Mechanics through Set-Level Mathematics

 In a recent article published in the journal AppliedMath, a new approach to understanding quantum mechanics (QM) was introduced, using a toy model over ℤ₂ to illustrate the concepts.

The New Approach

In this study, the author proposed a novel approach to QM by demonstrating that QM's distinctive mathematical formalism can be seen as the linearization of the mathematics of partitions on a set. This mathematical framework is used to represent distinctions/inequivalences and indistinctions/equivalences at the set level.

The paper elaborates on this new approach by using the vector space over the mathematics of partitions in its ℤ₂ form. The result is a non-relativistic, finite-dimensional toy model referred to as "quantum mechanics over sets" (QM/Sets). The main goal of this model is to provide pedagogical insights into some of QM's complex aspects using the simplest possible calculations (modulo 2) where 1 + 1 = 0.

This model aims to intuitively illustrate the typical oddities and paradoxes of QM, such as the double-slit experiment, without relying on the wave-interpreted mathematics over complex numbers (ℂ). In the model, integers modulo 2 are represented as ℤ₂ = {0, 1}, where vectors denoted by 0 and 1 are interpreted as sets, and the rules for addition and multiplication are uniquely defined so that 1 + 1 = 0.

In the QM/Sets toy model, Dirac brackets take on natural values, representing the cardinality of set overlaps. When probabilities are introduced via density matrices, real numbers are used, creating a more intricate model for depicting quantum phenomena.

The key concepts of partitions on a set include logical-level notions for modeling indistinctions versus distinctions, indefiniteness versus definiteness, or indistinguishability versus distinguishability. These concepts are critical for comprehending the QM's non-classical 'weirdness'. In QM, the primary non-classical notion is superposition, which is the notion of a state that is indefinite between two or more eigen- or definite states.

Vector Spaces over Z2

A vector space was formed using ℤ₂ by employing columns of 1s and 0s as the vectors. For instance, the column vectors are added component-wise, with each of the third, second, or first components adding to the other vector modulo 2's corresponding component in the three-dimensional (3D) vector space of column vectors like Z23.

Every component is viewed as the absence or presence of an element of a three-element set like U = {a, b, c} for interpreting these 3D column vectors in a meaningful way. Thus, the above addition operation would be {a, b} + {b, c} = {a, c}. Such addition on sets is known as the symmetric difference. The author used this set interpretation of


Z23/Z2n in general for the n-dimensional case of QM/Sets.

In quantum interpretation, the multiple-element subsets and single-element/singleton subsets represent superposition states/indefinite states of the quantum particle and eigenstates or definite states of a quantum particle, respectively. No state is represented by the empty set/zero vector. Definite states like {c}, {b}, or {a} form the basis for the vector space, as all other states/subsets can be derived by sums of them.

Double-Slit Experiment in QM/Sets

The author considered a setup where the three states in U = {a, b, c} primarily stand for the vertical positions for modeling the necessary aspects. A particle was sent from {b} to a screen having two slits at positions {c} and {a}. One time period took the particle to the screen, and the next time period took it to the wall.

In the first case, the superposition state {a, c} was reduced to {a} or to {c} with 1/2 probability upon detection at the slits. Subsequently, {a} evolved to {a'} = {a, b} and hit the detection wall at {b} or {a} with 1/2 probability, or {c} evolved to {b, c} and hit the wall at {c} or {b} with 1/2 probability in the next time period.

In the second case, the superposition state {a, c} evolved as a superposition/indefinite state as no state reduction occurred at the slits with no detection at the slits. The interference pattern's stripes characteristic was {a, b} + {b, c} = {a, c} without detection at the slits.

In this case, the evolution happened at a lower level/a level of indefiniteness, where the states {a, c} remained indistinguishable. Classical evolution takes definite states to definite states, as every state is distinguished in classical physics.

Overall, the simplified pedagogical model could allow the use of a lattice of partitions to assign an intuitive image to the classical world of entirely distinguished states and the quantum ‘underworld’ of indefinite states.

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B₄C–TiB₂ composite ceramics with adjustable mechanical and electrical properties

In recent years, electro-conductive composite ceramics have gradually become a research hotspot in the functionalization of structural ceramics. However, the improvement of conductivity is generally achieved at the cost of increasing the content of conductive phases or sacrificing the mechanical properties of the composite ceramics.

Therefore, achieving high conductivity of composite ceramics at low conductive phase content is of great significance. In a recent study, electrically conductive B4C–TiB2 composite ceramics containing only 15 vol% TiB2 were prepared by a two-step spark plasma sintering process, and their mechanical and electrical performances were adjusted by the optimal particle size coupling of raw material powders.

A team of material scientists led by Songlin Ran from Anhui University of Technology in Maanshan, China recently prepared highly electro-conductive B4C–TiB2 ceramics by a two-step spark plasma sintering method.

The three-dimensional interconnected intergranular TiB2 network consisting of large B4C grains and small TiB2 grains established an excellent conductive path for the passing of electrical current, which was beneficial to the improvement of electrical conductivity. Moreover, they have also achieved controllable adjustment of the mechanical and electrical properties of B4C–TiB2 ceramics by the optimal particle size coupling of raw material powders.

"In this work, we prepared highly electro-conductive B4C–TiB2 ceramics via a two-step method based on the novel selective matrix grain growth strategy. During the sintering progress, small B4C grains were completely consumed, leaving small TiB2 grains around B4C grains to form the three-dimensional interconnected intergranular TiB2 network.

"As a result, more conductive channels were formed and thus improving the electrical conductivity of the composites," said Dr. Ran, the corresponding author of the paper, a professor in the School of Materials Science and Engineering at Anhui University of Technology.

B4C–15 vol% TiB2 composite ceramic prepared from 10.29 µm B4C and 0.05 µm TiC powders exhibited a perfect three-dimensional interconnected conductive network with a maximum electrical conductivity of 4.25×104 S/m, together with excellent mechanical properties including flexural strength, Vickers hardness and fracture toughness of 691±58 MPa, 30.30±0.61 GPa and 5.75±0.32 MPa·m1/2, respectively, while the composite obtained from 3.12 µm B4C and 0.8 µm TiC powders had the best mechanical properties including flexural strength, Vickers hardness and fracture toughness of 827±35 MPa, 32.01±0.51 GPa and 6.45±0.22 MPa·m1/2, together with a decent electrical conductivity of 0.65×104 S/m.

"The method proposed in this paper can prepare highly electro-conductive ceramics at low conductive phase content, which greatly reduces the production cost and also provides a new strategy for the regulation of microstructure and properties of composite ceramics," said Dr. Ran.

The next step is to restructure the three-dimensional network and construct a more perfect conductive network by introducing ceramic particles, whiskers, fibers, etc. In addition, the effect of the multiple conductive phases on the microstructure, electrical properties and mechanical properties of the composite ceramics need to be investigated in detail to reveal the conductive mechanism.

Other contributors include Jun Zhao, Xingshuo Zhang, Zongning Ma, Dong Wang and Xing Jin from Anhui University of Technology in Maanshan, China; and Chaohu University in Hefei, China.

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Double-Step Shape Invariance in Quantum Mechanics

 An article recently published in the journal Axioms explored the double-step shape invariance of radial Jacobi-Reference (JRef) potential and the violation of conventional supersymmetric (SUSY) quantum mechanics rules.

Background

Laguerre-reference (LRef) and JRef are the two implicit potential families that are exactly solvable in terms of confluent hypergeometric or hypergeometric functions. These potentials are referred to as LRef and JRef potentials as they are quantized through classical Laguerre and classical Jacobi polynomials, respectively, using degree-dependent indices.

The JRef potential can be converted into a distinct rational function, referred to as the CGK potential, by the Darboux transformation with a nodeless eigenfunction as the transformation function. This implies that the exactly solvable potential like JRef is not shape-invariant, contradicting the renowned assertion of Gendenshtein that all exactly solvable potentials must be shape-invariant.

SUSY Rule Violation

This paper revealed some significant form-invariance features of the JRef canonical Sturm-Liouville equation (CSLE) in the particular density function case with the simple pole at the origin. It was proven that the CSLE preserves its form under the two second-order Darboux-Crum transformations (DCTs), with specially chosen basic quasi-rational solutions (q-RSs) pairs representing the seed functions to ensure that their analytical continuations do not possess zeros in the complex plane.

Additionally, both transformations often decrease or increase by two the exponent difference (ExpDiff) for the pole mentioned while keeping the other two parameters unchanged. The change can be more complicated if the ExpDiff for the original CSLE's pole is smaller than two at the origin. Researchers observed that bound energy levels are not preserved by DCTs according to conventional SUSY rules.

Specifically, they concluded that first-order differential expressions are generated by the mentioned second-order DCTs in the hypergeometric functions' space after the replacement of Crum Wronskians (CWs) by the Krein determinants (KDs). The predicted differential equations for the principal Frobenius solutions (PFSs) near the origin were explicitly confirmed using the conventional contiguous relations for hypergeometric series.

This mentioned anomalous case presented a good example of the breakup of the conventional SUSY quantum mechanics rules for DCTs between limit point (LP) and limit circle (LC) regions.

The Study and Findings

In this study, the researchers split the DCT into the two sequential Darboux deformations of the Liouville potentials associated with the CSLEs to understand the anomaly. Specifically, the anomaly source was explained by decomposing the second-order DCT into two sequential Liouville-Darboux transformations (LDTs).

The two different Liouville transformations on the infinite interval (1, inf) and on the finite interval (0, 1) then resulted in the supplementary double-step shape-invariant potential pair defined on the real axis and on the positive semi-axis, respectively. These potentials were solvable by the Heun equation's polynomial solutions.

The researchers observed that the initial CSLE was turned into the Heun equation written in canonical form by the first Darboux transformation, while the second transformation yielded the hypergeometric equation's canonical form. Additionally, the first of these transformations/first LDT placed the ExpDiff into the LC range, and then the second transformation/second LDT kept the pole/the given spectral problem within the LC region, which violated the conventional SUSY quantum mechanics prescriptions.

Significance of the Work

The significance of this study extends beyond the specific findings outlined here. It presented a specific illustration of the recently developed SUSY theory of the Gauss-reference (GRef) potentials representing the Liouville potentials for the confluent rational CSLE (RCSLE) with a single pole in the finite plane that is commonly placed at the origin, or two Fuchsian RCSLEs with three second-order poles, including infinity.

The RCSLE is referred to as Routh-reference (RRef), LRef, or JRef if it possesses q-RSs consisting of generalized Routh, Jacobi, or Laguerre polynomials. Most importantly, the eigenfunctions of the LRef and JRef CSLEs are composed of infinite sequences of classical Laguerre and classical Jacobi polynomials, with the polynomial indices typically reliant on the polynomial degrees in all three cases, while the RRef CSLE is quantized based on Romanovski/pseudo-Jacobi polynomials' finite orthogonal sequences.

In this work, the form-invariant RCSLE concept was extended to the JRef CSLE with the density function. The Liouville transformation can be performed independently on the three quantization intervals (−∞, 0), (1, ∞), and (0, 1), which leads to three Liouville potentials, including the radial potential studied in this work and the two branches of the linear tangent polynomial (LTP) potential on the line, which were found to be shape-invariant due to the action of second-order DCTs with basic solution pairs as the seed functions.

To summarize, this study effectively explained the breakdown of SUSY rules for the radial potential with a centrifugal barrier in the LC range.

Journal Reference

Natanson, G. (2024). Double-Step Shape Invariance of Radial Jacobi-Reference Potential and Breakdown of Conventional Rules of Supersymmetric Quantum Mechanics. Axioms, 13(4), 273.

International Research Awards on Mechanics of Functional Materials and Structures


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