Bosons and fermions, whether single-component or multi-component, have standard exchange statistics. Unlike anyons, there is no distinction required between particle permutations and particle exchanges; all exchange paths leading to the same permutation are equivalent. For standard exchange statistics, the Symmetrization Postulate is sufficient to describe wave functions of bosons and fermions. To implement the Symmetrization Postulate, bosons or fermions are given arbitrary particle labels, temporarily breaking indistinguishability. Then the artificial labels are made unobservable by symmetrizing or antisymmetrizing the wave function over these labels, effectively restoring indistinguishibility.

In more detail, consider $N$ particles with labels $i=1,2,\ldots,N$ and positions $x_{i}\in{\mathcal{M}}$ summarized in the vector ${\bf x}=(x_{1},\ldots,x_{N})$. When there are no points excluded by hard-core interactions then the configuration space is ${\mathcal{X}}={\mathcal{M}}^{N}$, otherwise ${\mathcal{X}}\subset{\mathcal{M}}^{N}$. The permutations $p=\{p_{1}p_{2}\cdots p_{N}\}$ of these labels form the symmetric group $S_{N}$ and correspond to coordinate transformations on ${\mathcal{X}}$ that map the point ${\bf x}=(x_{1},x_{2},\ldots,x_{N})$ to the point ${\bf x^{\prime}}=p({\bf x})=(x_{p_{1}},x_{p_{2}},\ldots,x_{p_{N}})$. Any permutation $p\in S_{N}$ can be expressed as a sequence of pairwise exchanges $s_{i}$ with $i=1,2\ldots,N-1$, each of which swaps the particle labelled $i$ with the particle labelled $(i+1)$. The transpositions $s_{i}$ form a generating set for the symmetric group and obey the relations

A way to visualize these permutations is in terms of strand diagrams as shown in Fig. 1. Instead of a permutation of labels or a coordinate transformation on ${\mathcal{X}}$, the strand diagrams depict particle exchanges as $N$ continuous paths. The horizontal direction represents space and the vertical direction represents time (or a control parameter) increasing from bottom to top. The rules (2.1) can be understood intuitively as the equivalences achievable by continuously transforming the strands (moving and stretching in space, while maintaining forward progress in time) and allowing strands to cross and overlap arbitrarily. For the symmetric group, every strand diagram leading to the same permutation is equivalent under the rules (2.1); this is not true for braid and traid strand diagrams below.

Applying the structural rules (2.1) to first-quantized wave functions for $N$ indistinguishable particles gives only two possibilities: bosons and fermions. To see this, consider the single-component (e.g., spinless or spin polarized) wave function $\psi({\bf x})$ defined on the configuration space ${\mathcal{X}}$. The probability $|\psi({\bf x})|^{2}$ to find particles at the positions ${\bf x}$ must be independent of the particle labels, so under the permutation $p$ of particle labels the wave function can only change by a phase factor $\eta_{p}$. Let the operator $\hat{U}$ be a representation of $S_{N}$ on the Hilbert space of wave functions on ${\mathcal{X}}$ defined by

The phase factors $\eta_{p}$ provide an abelian representation of the symmetric group, so they must obey the constraints related to Eqs. 2.1. Denoting $\sigma_{i}$ as the phase associated with the permutation $s_{i}$, then an exchange of adjacent pairs gives $\hat{U}_{s_{i}}\psi({\bf x})=\sigma_{i}\psi({\bf x})$. From Eq. (1a), we have that $\psi(s_{i}^{2}({\bf x}))$ is equal to both $\sigma_{i}^{2}\psi({\bf x})$ and $\psi({\bf x})$, implying that $\sigma_{i}=\pm 1$. In turn, from the Yang-Baxter relation (1b), we obtain $\psi(s_{i}s_{i+1}s_{i}({\bf x}))=\sigma_{i}^{2}\sigma_{i+1}\psi({\bf x})$ is equal to $\psi(s_{i+1}s_{i}s_{i+1}({\bf x}))=$ $\sigma_{i}\sigma_{i+1}^{2}\psi({\bf x})$, implying that $\sigma_{i}=\sigma_{i+1}$ for all $i$. For abelian representations, locality (1c) provides no constraints on the phases. All together, we find that all phases are equal:

where the two possible choices correspond to bosons and fermions, respectively ²²2Note that a similar argument also holds for multi-component wave functions but requires non-abelian representations of the symmetric group. For a detailed exposition on the Symmetrization Postulate in 1D, see [26, 27]..

In 2D with hard-core two-body interactions, the equivalence between permutations of particle labels and particle exchanges no longer holds. Instead of the symmetric group $S_{N}$, particle exchanges for $N$ indistinguishable particles are described by the braid group $B_{N}$ [1, 2, 4, 5]. Because particles cannot coincide, the configuration space is not simply-connected and multi-valued wave functions are allowed; see Appendix B for more details on how the braid group derives from topological exchange statistics.

The key structural features of the braid group can be understood by considering strand diagrams. Unlike the symmetric group, when two paths in the diagram cross, the particles cannot coincide and so we must indicate which particle is passing in front. As a result, the exchange of two particles is no longer self-inverse; the braids $b_{i}$ and $b_{i}^{-1}$ are the distinct over- and under-braided exchanges of the particles labeled $i$ and $i+1$; see Fig. 2(b) and (c). With this distinction, the diagrams of Fig. 1 have to be modified as shown in Fig. 3. However, both the Yang-Baxter and locality relations are preserved because, unlike the self-inverse relation, continuous deformations of the strands described by those relations are not disrupted by the two-body hard-core constraints. Note that in three spatial dimensions also for hard-core interactions no distinction between over and under can be made since both diagrams can be transformed into each other using the third dimension. In one dimension, in turn, two-body hardcore interactions prevent any particle exchange. Thus, in the continuum, braid anyons are naturally expected to occur only in 2D. However, we show below how the discrete configuration space of a lattice allows for the definition of braid anyons also in 1D.

Every particle exchange $\gamma\in B_{N}$ can be represented as the product of $b_{i}$ and $b_{i}^{-1}$’s. These generators obey the relations

Note that unlike the symmetric group, the same particle permutation can be enacted by multiple inequivalent exchange paths $\gamma\in B_{N}$. For example, the braids $b_{1}$, $b_{1}^{-1}$, $b_{1}^{3}$, $b_{1}^{-3}$, etc., all enact the same particle permutation of the first and second particles. The multi-valuedness of anyon wave functions on ${\mathcal{X}}$ originates from the multiplicity of topologically distinct exchange paths that execute the same permutation. Unlike the Symmetrization Postulate, elements of the braid group do not correspond to coordinate transformations on ${\mathcal{X}}$. However, we can define an operator $\hat{U}_{\gamma}$ that represents a particle exchange $\gamma\in B_{N}$, and for an abelian representation, $\hat{U}_{b_{i}}$ multiplies the wave function by a phase factor $\beta_{i}$:

Because the generators are no longer self-inverse, the phase $\beta_{i}$ can take any value. As a result of the Yang-Baxter relation, as before we have $\beta_{i+1}=\beta_{i}$ and all the $\beta_{i}$ are required to be equal. Therefore, we obtain the continuous family of possible choices for abelian representations of $B_{N}$

labeled by the exchange phase $\theta$. The special cases $\theta=0$ and $\theta=\pi$ correspond to bosons and fermions, respectively, and lead to single-valued wave functions on ${\mathcal{X}}$. All other $\theta$ correspond to braid anyons with fractional exchange statistics and have wave functions that are multi-valued on ${\mathcal{X}}$ [6].

The equivalence between permutations of particle labels and particle exchanges also no longer holds when there are three-body hard-core interactions in 1D. The excluded points in configuration space are defects that result in topological exchange statistics described by the traid group $T_{N}$ [16, 17]. See App. C for how the traid group is derived from topological exchange statistics.

To understand the resulting exchange statistics, we can again modify the strand diagrams of Fig. 1, as shown in Fig. 4. Since we do not assume a two-body hard-core constraint, two strands can cross, just like in Fig. 1; there is no “over” or “under” distinction intrinsic to 1D, unless we encode this information in additional degrees of freedom like relative velocity. We can immediately verify that the exchange of particles is self-inverse and local. However, the Yang-Baxter relation is broken; there is no continuous deformation of the strand diagram on the left-hand side of 1(b) to that on the right-hand side of 1(b). Such a deformation would necessarily involve crossing of three strands in one point, violating the three-body hard-core constraint.

As before, we can define generators $t_{i}$ for the exchange of the $i$th and $(i+1)$th particles that obey relations that we can read off Fig. 4:

With these relations, the $N-1$ generators $t_{i}$ define the traid group $T_{N}$ for $N$ strands. Note that while for the symmetric group the labels $i$ were an arbitrary assignment, and for the braid group the labels were based on an arbitrary positioning of the particles, in 1D there is a natural way to assign labels based on their ordering on the line; i.e. the particle furthest to the left (or equivalently, right) is the particle labeled $i=1$, then the next particle in order is labeled $i=2$, and so on. This ordering scheme is invariant under homeomorphisms of the line, and ordinality (so defined) is a topological property intrinsic to 1D systems. Therefore, unlike the pairwise exchange generators of $S_{N}$ or $B_{N}$, the generator $t_{i}$ exchanges neighboring particles in real space, not just in label space. This topological feature of ordinality is intimately connected with the breaking of the Yang-Baxter relation (7b).

Irreducible abelian representations of the traid group are specified by the phases $\tau_{i}$ picked up during the exchange of neighboring particles

where the operator $\hat{U}_{t_{i}}$ represents the generator $t_{i}$. The self-inverse relation (7a) ensures that, like for standard $S_{N}$ statistics, $\tau_{i}=\pm 1$. However, unlike both standard and braid statistics, where the Yang-Baxter relation (7b) enforces equality of the phases, for the traid group the phase factors $\tau_{i}$ are independent (generally, $\tau_{i}\neq\tau_{j}$). Thus, we have

leading to $2^{N-1}$ abelian representations of the traid group, corresponding to the $N-1$ choices of signs $\tau_{i}$. Like braid anyons, traid anyons contain bosons and fermions as special cases, here corresponding to all $\tau_{i}=+1$ or all $\tau_{i}=-1$, respectively. Unlike braid anyons, traid anyon representations do not continuously interpolate between these two extreme cases, but instead comprise a discrete set with non-standard exchange statistics.

To better understand traid anyon representations, consider the simplest non-trivial case of $N=3$ particles. Besides bosons $(\tau_{1},\tau_{2})=(+1,+1)\equiv(++)$ and fermions $(--)$, there are two additional abelian representations $(+-)$ and $(-+)$. For the representation $(+-)$, the first pair of particles exchanges symmetrically like bosons and the second pair exchanges antisymmetrically like fermions. For either of these cases, the products $\tau_{1}\tau_{2}\tau_{1}$ and $\tau_{2}\tau_{1}\tau_{2}$ have opposite signs, showing that the same permutation of the first and third particle can be accomplished through topologically distinct exchange paths.

To introduce the anyon-Hubbard model, we follow Ref. [11] and begin from the deformed commutation relations hypothesized for fractional exchange statistics:

where $a_{j}$ is the annihilation operator for an anyon obeying fractional exchange statistics described by exchange phase $\theta$. In terms of these operators, the anyon-Hubbard Hamiltonian is then

where $n_{j}=a_{j}^{\dagger}a_{j}$ is the number operator on site $j$, $J$ is the tunneling strength, and $U$ is the two-body interaction strength.

The anyonic creation and annhihilation operators with commutation relations (10) can be expressed in terms of bosonic ones $b_{j}$ via a generalized gauge transformation called the fractional Jordan-Wigner transformation:

where also $n_{j}=b_{j}^{\dagger}b_{j}$. This density-dependent gauge transformation (12) is non-local because the phase for the operator $a_{j}$ depends on all occupation numbers to the left of site $j$. Although the fractional Jordan-Wigner gauge transformation is non-local, the deformed commutation relations (10) remain local.

Expressed in terms of boson operators, the anyon-Hubbard Hamiltonian (11) becomes

In the bosonic form, there are operator-valued, occupation-number-dependent Peierls phases attached to the tunneling matrix elements. These phases break parity, and they occur when a particle hops to the right onto an already occupied lattice site [Fig. 5(a)] or in the hermitian conjugate process when a particle hops to the left from a multiply occupied lattice site.

These Peierls phases can give rise to non-trivial geometric phases associated with closed paths in the many-body configuration space of indistinguishable particles, given by all Fock states with sharp site occupation numbers. Such geometric phases can be viewed as generalized magnetic fluxes. In Fig. 5(b), we show an example of a Fock-space loop associated with a nontrivial phase of $\theta$ ($-\theta$), when encircled in clockwise (anticlockwise) direction. Recently, the bosonic representation of the anyon-Hubbard model (13) was realized experimentally with ultracold atoms in an optical lattice, where the non-trivial geometric phases were probed directly via interference of the upper and the lower path of Fig. 5(b) during quantum walks [14].

The geometric phase resulting from the density-dependent tunneling can be directly related to the braiding of particles. In Fig. 5(b), we can associate paths that encircle the depicted loop, starting (say) from the leftmost configuration, with the exchange of the two particles. Encircling the loop in clockwise direction, so that the left particle tunnels rightwards twice, passing an occupied site, can be associated with $b_{i}$ depicted in the strand diagram Fig. 2(b), where the left particle moves over the right one. In turn, encircling the loop in anticlockwise direction, so that the right particle tunnels leftwards twice, passing an occupied site, can be associated with $b_{i}^{-1}$ depicted in the strand diagram Fig. 2(c), where the right particle moves over the left one. The corresponding phase factors are $\beta_{i}=\beta=e^{-i\theta}$ and $\beta_{i}^{-1}=\beta^{*}=e^{i\theta}$. In this sense, the anyon-Hubbard model describes braid anyons. Therefore, and in order to distinguish it from the traid-anyon-Hubbard model that we construct in the next subsection, we will also refer to it as the braid-anyon-Hubbard model in the following.

The goal of this section is to introduce a lattice model of interacting bosons that captures traid anyonic exchange statistics. For this purpose, we will reverse the strategy used for the braid-anyon-Hubbard model above to implement these extreme cases. Namely, we first construct a bosonic model with non-local number-dependent tunnelling phases that give rise to the desired exchange phases. Then we find the corresponding traid anyon field operators and their commutation relations by constructing a generalized Jordan-Wigner transformation, so that the kinetic energy term of the Hamiltonian becomes quadratic and local with respect to these new operators. We will first focus on the case of staggered abelian representations of the traid group, with alternating exchange phases given by $(+-+-\cdots)$ and $(-+-+\cdots)$. These are of specific interest, since they are furthest away both from the bosonic and (pseudo)fermionic cases, characterized by the homogeneous exchange phases $(++\cdots+)$ and $(--\cdots-)$, respectively. Subsequently, we will also construct a model for general abelian representations $(\tau_{1},\tau_{2},\ldots,\tau_{N-1})$ with $\tau_{i}=+1$ or $-1$ of the traid group.

A model that realizes the two abelian representations of the traid group with alternating exchange phases is achieved by the following lattice model using bosons with number-dependent hopping phases,

In contrast to the braid-anyon-Hubbard model (13), the number-dependent hopping phase is now defined in terms of the operator

that counts the number of particles to the left of (and including) lattice site $j$. The integer $I\in\{0,1\}$ that appears in the phase determines which of the two possible abelian representations of the traid group with alternating exchange phases the model realizes: For $I=0$ we have $(+-+-+\cdots)$, meaning that the two leftmost particles exchange like bosons, the second and third particles from the left exchange like fermions, and so on. For $I=1$ on the other hand, the pattern $(-+-+\cdots)$ gets flipped, i.e. the two leftmost particles now exchange like fermions.

The symmetries of the lattice traid anyon model can be inferred from the bosonic form of the Hamiltonian (14). Time reversal invariance $\mathcal{T}H\mathcal{T}=H$ results by observing that $\exp(i\pi k)$ $=\exp(-i\pi k)$ for any integer $k$, so the Peierls phase is invariant under complex conjugation, as are all other terms. Spatial inversion $\mathcal{P}$ transforms $j$ to $L-j$ and $N_{j}$ to $N-N_{j}$. After reindexing the sum, the only difference between $\mathcal{P}H\mathcal{P}$ and $H$ that remains is an additional phase $\exp(i\pi N)$ in the hopping terms. Therefore, for $N$ even, we have $\mathcal{P}H(I)\mathcal{P}=H(I)$ with the same $I$ whereas for $N$ odd we have $\mathcal{P}H(I=0)\mathcal{P}=H(I=1)$. In comparison, neither $\mathcal{T}$ nor $\mathcal{P}$ are symmetries of the braid-anyon-Hubbard model, although a gauge-transformed combination of them is [28].

Figs. 6(a-c) depict these alternating hopping phases $(+-+)$ for the case of 4 particles and $I=0$: When the leftmost particle hops to the right onto an already occupied lattice site [Fig. 6(a)], a phase factor of $+1$ gets picked up. Tunneling to the right onto an empty site always gives a trivial phase factor, and so if that particle were to then hop onto another empty site (not depicted), the two particles would be exchanged in order with an overall exchange phase factor of $+1$. Exchanging the third and fourth particle gives the same result, while a swap of the central two particles [Fig. 6(c)] results in an overall phase factor of $-1$, i.e. the second and third particles exchange like fermions. Figs. 6 (d,e) show how these phases accumulate during particle exchanges. We can see that, like for the braid-anyon-Hubbard model, the number-dependent Peierls phases give rise to the desired exchange phases.

Note that our lattice model in Eq. 14 uses bosons and thus allows an arbitrary number of particles to occupy the same lattice site. However, a three-body hard-core constraint is essential for the existence of genuine traid anyons in the continuum. Indeed, if we consider hopping processes on the lattice involving three or more particles, the desired pattern of alternating exchange phases breaks down for our model. We can address this problem theoretically in two ways: we can add a three-body interaction term to the Hamiltonian (14) and take the limit of the coupling coefficient to infinity, or we can implement the three-body hard-core constraint algebraically by requiring $b_{j}^{3}=0$. For numerical convenience, we have chosen the latter approach by simply truncating the state space so that at most two particles can occupy the same site. Note that if we restrict ourselves to the low-energy, dilute limit, then three-body occupation of the same site becomes increasingly unlikely to occur and should be negligible for the calculation of most observables. Our numerical results in the next section show that this is indeed the case for the low-energy dilute limit. Further, in the following section on the continuum limit we show that three-body, hard-core interactions emerge naturally from the number-dependent tunneling phases for the alternating representations.

We now define annihilation and creation operators, $t_{i}$ and $t_{j}^{\dagger}$, for the traid anyons. For that purpose, we define a generalized Jordan-Wigner transformation, so that the kinetic part of the Hamiltonian describing tunneling becomes local and quadratic with respect to these new operators:

For the staggered traid anyon model (14), this is achieved by:

where $M_{j}$ depends on the $N_{j}$ (15) and on the integer $I$ (determining which of the two representations with staggered exchange phases is realized in Eq. 14). Like the braid-anyon-Hubbard model, the transformation (3.2) leaves the number operator on site $j$ invariant

The crucial difference is that when expressed in the bosonic form, the hopping phases of the traid anyon model (14) are non-local and depend on the notion of ordinality, whereas hopping phases for the braid-anyon-Hubbard model are local.

This non-local property is noticeable also in the commutation relations for the traid operators $t_{j}$. From Eq. 3.2 and the bosonic commutation relations, we obtain:

where $N_{jk}$ are new operators defined as

From Eqs. 3.2, we see that the commutation relations of the traid anyon operators reduce to the bosonic case when acting on the same lattice site. However for operators acting on different sites, the commutation relations are either fermionic or bosonic, depending on the configuration of all the other particles on the lattice.

The traid anyon lattice model (14) generalizes to arbitrary abelian representations of the traid group in the following way:

where $F(N_{j})$ is a polynomial of $N_{j}$ (15) that takes on even or odd integer values for integer inputs. $F(N_{j})$ differs for each abelian representation and takes on the simplest form for the alternating cases: $F_{\text{alt}}(N_{j})=N_{j}+I$. For example, if one wanted to construct a model to realize the representation $(++-)$ for 4 traid anyons, we would need to find a polynomial that takes on the values $F_{++-}(0)=0$, $F_{++-}(1)=0$ and $F_{++-}(2)=1$ (or equivalently other even/odd integer values). In practice, for our numerical simulations in Sec. 4, we do not construct the polynomial explicitly and only set the desired inputs/outputs.

Analogously, we can find a Jordan-Wigner-like transformation that brings the generalized Hamiltonian of the traid anyon model (21) to the form (11) with a quadratic nearest neighbor tunneling term:

where $f(N_{j})$ is a polynomial of $N_{j}$ (15), taking on odd or even integer values depending on the traid group representation which is to be realized. In particular, $f(N_{j+1})-f(N_{j})=F(N_{j})n_{j+1}$ should be fulfilled, so that the kinetic term in Eq. 21 is quadratic when expressed in terms of these general traid anyon operators. For example, to construct traid anyon operators for the representation $(++-)$, we can set $f(0)=f(1)=f(2)=0$ and $f(3)=1$. It is easy to check that this yields the desired pattern of tunneling phases, provided we exclude three-body coincidences. Similarly, the generalized transformation (22) leads to generalized commutations relations for the $t_{j}$.

We note that the transformation defined in Eqs. 3.2 for the alternating abelian representations does not match the general form given by Eq. 22: the operator $M_{j}$ is not just a polynomial of $N_{j}$ but also depends on the configuration of the particles to the left of site $j$ (and not just their number). For instance, a two-body coincidence to the left of site $j$ would result in an extra factor of $-1$ in $e^{-i\pi M_{j}}$. These potential additional factors of $-1$ cancel out for terms of the form $t_{j+1}^{\dagger}t_{j}$ or $n_{j}=t_{j}^{\dagger}t_{j}$ and have thus no influence on the Hamiltonian in Eq. 16. On the other hand, for observables like the two-point correlation function $\braket{t_{i}^{\dagger}t_{j}}$, it can indeed make a difference, e.g. if there is a two-body coincidence between lattice sites $i$ and $j$. The factor of $-1$ then only occurs for one of the traid anyon operators and does not cancel out. The advantage of using the traid anyon operators defined in Eqs. 3.2 for the alternating abelian representations instead of the general form given by Eq. 22, is that the transformation to boson operators always results in the conceptually simple Hamiltonian in Eq. 14, even if we do not enforce a three-body hard-core constraint.

Finally, we would like to point out that the representation of traid anyons using bosons with number dependent tunneling matrix elements resembles the composite-particle picture of braid anyons in 2D (see, e.g. Ref. [6]). In the latter case, 2D braid anyons are mapped to charged bosons (or fermions) to which a magnetic flux is attached to implement the geometric phases picked up when particles are moved around each other. In the former case of our traid anyon lattice model, the number dependent tunneling matrix elements also give rise to generalized magnetic fluxes in the discrete configuration space of our system that are determined by the position of the particles and implement the geometric phases associated with the exchange of traid anyons; [See e.g. Figs. 5(b) and 6(e)].

As a first physical observable, we consider the ground state particle densities. The particle density is independent of whether we formulate the model in terms of boson or traid anyon operators: $\braket{n_{j}}=\braket{b_{j}^{\dagger}b_{j}}=\braket{t_{j}^{\dagger}t_{j}}$, i.e. the number of bosons and traid anyons on each lattice site is identical. Fig. 7 shows the ground state densities of 3 to 6 traid anyons on $20$ lattice sites. We depict the two possible abelian representations with alternating exchange phases ($+-+-...$) and ($-+-+...$) for each number of particles. As expected, the reflection symmetry of the densities about the midpoint of the lattice embodies the symmetry of the arrangement of the exchange phases: While the individual density profiles for the representations with $I=0$ and $I=1$ are not symmetric for odd $N$, they are mirror images of each other. In turn for even particle numbers, we find distinct, individually symmetric densities.

Examples of non-alternating abelian representations of the traid group are shown in Fig. 8, where the densities of all $8$ possible abelian representations (not just the alternating case) for $4$ particles are represented. The top left plot depicts the trivial case of bosons and pseudo-fermions, where all exchange phases are identical. The bottom two plots show 4 representations which can only be realized by the generalized version of our lattice model (21).

The density profiles depicted in Figs. 7 and 8 show that for each minus sign in the chosen traid-group representation, there is a minimum separating two local density maxima. Intuitively, depending on the exchange phases on both sides of the minus sign, these maxima are associated with either single particles resembling fermions, or two particles forming a ‘bosonic’ pair (separated by fermionic exchanges from its neighbors). For non-alternating traid group representations, when there are several plus signs next to each other, also ‘bosonic’ triples, quadruples, etc. can be observed (see Fig. 8). In the case of pseudo-fermions, i.e. the representations $(---\cdots)$ with only minus signs (see the top left plot in Fig. 8), these oscillations of the density correspond to Friedel oscillations [29], as they have been predicted also for the braid-anyon-Hubbard model [13]. These oscillations are a result of the fermionic two-particle correlations (reflecting Pauli exclusion), as they become visible in the density distribution close to a local defect, which is here given by the edge of our finite system with open boundary conditions. Thus, for the non-trivial representations, containing both plus and minus signs, the observed oscillations can be viewed as generalized Friedel oscillations.

Like the particle densities discussed above, the ground-state energy (as well as the full spectrum) does not depend on whether we consider bosons with number-dependent tunneling phases or traid anyons, since the Hamiltonians for both pictures are equivalent due to the construction of the transformation between them (3.2). We numerically calculate the ground state energies $E_{0}$ of our lattice model and consider the zero-temperature chemical potential, i.e. the ground state energy difference $E_{0}(N)-E_{0}(N-1)$ of a system with $N$ and $N-1$ respective particles. Note that this quantity is well defined only for a specific rule for how the sign $\tau_{N}$ is chosen, when the $(N+1)$st particle is added to the system.

The chemical potential directly provides a perspective on the relation between exchange statistics and exclusion statistics (see Appendix D below). Free bosons and free fermions (where by “free” we mean non-interacting) are the extreme cases. Any number of bosons can occupy the ground state, so each additional particle requires the same amount of energy, whereas each additional fermion must occupy the next higher single-particle energy eigenstate. Free particles with fractional exclusions statistics, where single-particle states can be occupied by a well defined finite number of particles, would, in a similar fashion, give rise to a clear fingerprint in the behaviour of the chemical potential as a function of the total particle number. Below, we will, indeed, see traces of such behaviour, but also deviations from it, which will be attributed to the fact that, as a result of the number-dependent tunneling phases, even for $U=0$ the traid-anyon Hubbard model does not describe free particles.

We show the results for a system with $30$ lattice sites, up to $10$ particles and no on-site interactions ($U=0$) in Fig. 9. We compare the two realizations of traid anyons with alternating exchange phases (14) to (spinless) fermions, pseudo-fermions, bosons, and to the braid-anyon-Hubbard model (13) with exchange phase $\theta=\frac{\pi}{2}$.

The ground state energies of free fermions and free bosons can be calculated analytically from the single-particle energies $E(k)=-2J\cos(dk)$ of a system with $M$ lattice sites, lattice spacing $d$, and allowed quasi-momenta $k=\frac{\pi\nu}{d(M+1)}$ with $\nu=1,2,...,M$. For the bosonic ground state all bosons occupy the single-particle ground-state, thus $E_{0}(N)-E_{0}(N-1)=$ $-2J\cos(\pi/(M+1))$. For (spinless) fermions on the other hand, the Pauli exclusion principle implies that $E_{0}(N)-$ $E_{0}(N-1)$ $=-2J\cos(N\pi/(M+1))$. The ground state energies of the traid-anyon-Hubbard and braid-anyon-Hubbard model (13) were obtained numerically using exact diagonalization for $N<7$ and DMRG for $N\geq 7$. For completeness, we have also included pseudo-fermions corresponding to the $(--\cdots-)$ representation of the traid-anyon Hubbard model as well as to the braid-anyon-Hubbard model with $\theta=\pi$. Their chemical potential agrees nicely with that of free fermions in the dilute regime (roughly below quarter filling or $N=7$), but as the density increases one can see a deviation because multiply-occupied sites are allowed for pseudo-fermions, unlike for true fermions.

We chose the braid-anyon-Hubbard model with exchange phase $\theta=\frac{\pi}{2}$ for comparison, because it provides a different notion of particles exhibiting behaviour ‘right in the middle’ between fermions and bosons: the anyons in the braid-anyon-Hubbard model always exchange with the same phase $\theta=\frac{\pi}{2}$, averaging between bosonic and fermionic behavior. In contrast, traid anyons in the representations $(+-+-...)$ or $(-+-+...)$ alternate between exchanging fermion-like (corresponding to an exchange phase $\theta=\pi$) and boson-like ($\theta=0$). These different notions of interpolation between fermions and bosons are also reflected in the chemical potentials in Fig. 9. While the chemical potential lies approximately in the middle of the fermionic and bosonic case for both traid anyons and the braid-anyon-Hubbard model with $\theta=\frac{\pi}{2}$, the behaviour is nonetheless strikingly different: We observe a smooth increase of the potential for the braid-anyon-Hubbard model, while the traid anyons exhibit a step-like behaviour, where the change in the chemical potential increases or decreases in an alternating fashion.

The step-wise increase of the chemical potential, observed for the staggered traid anyons, can be interpreted as a signature of approximate Haldane-like semionic fractional exclusion statistics, i.e. of a generalized Pauli exclusion principle, where single-particle states can be occupied by up to two particles (c.f. App. D). Ideally, such behaviour might be associated with the chemical potential increasing for every other particle added and staying constant otherwise. We, however, find that rather than staying constant in the latter case, the chemical potential decreases. This hints at an effectively induced attractive interaction, something previously noted for the braid-anyon-Hubbard model [30]. In the next subsection, where we investigate the natural orbitals and their occupations, we find further evidence for the emergence of approximate fractional exclusion statistics and an explanation for the observed decrease of the chemical potential in every other step.

The emergence of semionic exclusion statistics can be understood intuitively as a consequence of the staggered exchange statistics of the traid anyons. Namely, when the rightmost particles form a ‘bosonic’ pair, a newly added particle comes with a minus sign and thus plays the role of a new single ‘fermion’ on the right edge. In turn, when the rightmost particle resembles a single ‘fermion’, the added particle comes with a plus sign, so that it can occupy the same space as the former rightmost particle (both form a new ‘bosonic’ pair).

It is straightforward to generalize these ideas to non-staggered representations. We then expect to find scenarios where 3 (or more) neighboring particles behave like bosons to each other, e.g. for $(++-++-...)$. Also mixed fractional statistics can be imagined, e.g. for $(+-++-+-...)$ pairs and triples of particles are expected to be in the same state. Such cases will be discussed in the next subsection.

The natural orbitals are defined as the eigenvectors of the single-particle density matrix (SPDM) $\langle c_{i}^{\dagger}c_{j}\rangle$, where $c^{\dagger}_{i}$ and $c_{j}$ are generic creation and annihilation operators, respectively. The corresponding eigenvalues are the natural orbital’s occupation numbers that represent how many particles occupy each natural orbital on average. For free the many-body ground state of free bosons ($c_{i}=b_{i}$) the single eigenvector with non-zero eigenvalue of the SPDM would be the state-space vector of the single-particle ground state and the corresponding eigenvalue would give the occupation $N$ of that state. For free fermions, one finds $N$ eigenvectors with non-zero eigenvalues of $1$, corresponding to the singly-occupied single-particle energy eigenstates forming the Fermi sea. Considering interacting bosonic or fermionic systems, the natural orbitals no longer correspond to the single-particle energy eigenstates and the occupation numbers of the natural orbitals are generally not integer valued anymore. For free particles with fractional exclusion statistics, one would expect eigenvalues corresponding to occupations that take integer values larger than one, but smaller or equal than an allowed maximum occupation (e.g. two for so-called semions). Below, we indeed find approximately such behaviour, with small deviations that we attribute to the presence of interactions associated with the number-dependent tunneling even for $U=0$.

In order to investigate the properties of the traid anyons, we need to consider the SPDM with respect to the traid-anyon operators,

Note that it is different from the bosonic one, $\braket{t_{i}^{\dagger}t_{j}}\neq\braket{b_{i}^{\dagger}b_{j}}$. An intuitive understanding of how the occupation numbers for hypothetical free traid anyons would look like a given traid group representation $(\tau_{1},\ldots,\tau_{N}-1)$ can be gained as follows: Whenever there is a string of $\tau_{i}=+1$ of length $m$ in a representation, then those $m+1$ particles exchange like bosons and can all occupy the same state. Whenever there is $\tau_{i}=-1$ in a representation, a new orbital must be added to account for the antisymmetric exchange. For example with $N=3$, the alternating representation $(+-)$ would have one orbital localized on the left with occupation number $2$ corresponding to the two particles with boson-like exchanges, and one orbital with occupation number $1$ localized on the right side. The representation $(-+)$ would have the same occupation numbers as $(+-)$ but mirrored orbitals. For $N=4$, the ground state of representation $(-+-)$ would have three orbitals, one with occupation number $2$ localized in the center, and two with occupation number $1$ localized on the sides, whereas $(+-+)$ would have two orbitals with occupation number $2$ localized on either side. Generally, all alternating representations will have a maximum occupancy of $2$, i.e., semionic exclusion statistics. The reasoning presented in this paragraph has to be taken with a grain of salt, as the actual natural orbitals are delocalized (as is know for instance for the case of free fermions). But it provides an intuitive understanding of the expected fractional exclusion statistics, as we indeed find it in our numerical results below (up to corrections which we attribute to the presence of interactions even for $U=0$ associated with the number dependent tunneling).