Effective HamiltonianS of the large-s pyrochlore antiferromagnet
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1 Effective HamiltonianS of the large-s pyrochlore antiferromagnet Uzi Hizi and Christopher L. Henley, with Prashant Sharma (on part 3) [Support: U.S. National Science Foundation] HFM 2006, Osaka, August 17,
2 Effective HamiltonianS of the large-s pyrochlore antiferromagnet: outline 0. Introduction: pyrochlore lattice (vs. Bethe lattice); effective Hamiltonians 1. Harmonic-order spinwaves [CLH, PRL 96, (1006)] [U. Hizi & CLH, PRB 73, (2006)] [2.]. Quartic-order spinwaves [U. Hizi & CLH, unpublished; see U. Hizi Ph. D. thesis, 2006] [3.] Large-N [Sp(N)] mean-field theory [U. Hizi, P. Sharma, and C. L. Henley PRL 95, (2005)] [4.] Conclusions: (i) comparison to kagomé (ii) related systems (field plateaus)? (iii) spin disordered states?? 2
3 0. Introduction Pyrochlore lattice Corner sharing tetrahedra = bond midpoints of diamond lattice 3
4 Hamiltonian: Heisenberg Antiferromagnet H = J ij S i S j = 1 2 tetra. α L α 2 + const. L α i α S i = 0 (tetrahedron sum in ground state) Classically, any state with L α = 0 is ground state. Massive degeneracy rich phase diagrams of correlated states Our question: what is S 1 ground state? expect spin order!. disordered for classical [Moessner & Chalker 1998]... or for S = 1/2 [Canals & Lacroix 1998] 4
5 Experimental pyrochlore systems? Many A 2 B 2 O 7 oxides (pyrochlore structure) or AB 2 O 4 (spinels): Gd 2 Ti 2 O 7 : noncollinear (dipolar interaction) [Champion et al, PRL 2001 ZnCr 2 O 4 : S = 3/2; Heisenberg behavior but distortion at lower T (magnetoelastic interaction) [S. H. Lee et al, PRL 2000, Nature 2002; see Tchernyshyov PRL 2002, 2004] CdCr 2 O 4 : Magnetization plateau; complicated helical ordering (Dzyaloshinskii-Moriya) [J.-H. Chung et al, PRL 2006] Future clean realizations in cold gases? [e.g. L. Santos et al 2004, theory kagomé optical lattice] 5
6 Effective Hamiltonian notion Expect perturbation energies E to split the degeneracies. Usual approach: (i) guess 2 or 3 simple/high symmetry states (ii) compute E for each (iii) compare Our approach: define a function H eff for every state. Advantages and disadvantages + If true ground state isn t one of those you guessed!? + Building block: (i) T > 0 simulation (ii) H eff + disorder, anisotropy, or tunneling among discrete states Usually uncontrolled expansion, crude (truncated) form. Want: (i) analytic form (ii) energy scale (iii) ground states (iv) their degeneracy 6
7 Remark: Bethe lattice versus loops We ll see the important states are discrete, like Ising model. On Bethe lattice, all Ising states are symmetry equivalent (hence exactly degenerate) In pyrochlore lattice, effective Hamiltonian H eff must depend on loops. 7
8 1. Harmonic-order H eff Zero-point energy Break degeneracy with zero-point spin wave energy: E harm ({ˆn i }) m 1 2 hω m = O(JS) E class = O(JS 2 ) Implicitly function of classical directions {ˆn i } Splits states because different magnon spectra Collinear ground states ˆn i = η i ẑ favored by E harm. Assume minimum E harm is collinear state. E harm ({η i }) will give H eff harm. 8
9 Spinwave equation of motion Linearized eqn. of motion for ordinary spinwave modes? [the other modes have ω = 0] Reduces to one for tetrahedron spin L α : δ L α = SJ β µ αβ ẑ δl β, (1) µ αβ η i(αβ) (2) [i(α, β) pyrochlore site between diamond lattice sites α and β]. The dynamical matrix µ is the classical configuration {η i }. (And its eigenvalues are ω m.) 9
10 Trace expansion for harmonic energy E harm Eigenvalues of matrix µ 2 are ( hω m ) 2. E harm ({η i }) 1 2 hω m = JSTr m ( ) 1 4 µ2 Formally Taylor-expand square root about constant matrix A E harm = [ ( )] µ 2 1/2 STr A + 4 A (3) = S c 2k A (k 1/2) Tr (µ 2k ) (4) k=0 [{c 2l } have closed expressions] [Result converges to A-indep. result, as long as A > 1.4]. : 10
11 Loop expansion Each term of E harm is Tr(µ 2k ): a sum over products of 2k µ αβ s: i.e., η i (Ising spins) on all possible closed paths of 2k steps. Retraced portions: trivial factors η 2 i 1 ( decorations ). To resum, approximate (well) by Bethe lattice paths. Path around a loop: contributes configuration-dependent factor ηi around that loop. 11
12 Loop expansion 2 [Recall: Zero-point energy was:] ( ) 1 E harm = JSTr 4 µ2, µ αβ η i(αβ). Example of two factors in a term: η i(αβ) βη i(γβ) 4 α = γ (µ 2 ) αγ = η i(αβ) η i(βγ) α, γ next-nearest neighbors 0 otherwise α γ 12
13 Result: Loop effective Hamiltonian H eff harm = N spins Φ Φ (Here Φ 2l 2l k=1 η i k.) Numerical check (from database of numerous ground states.) 13
14 Gauge-like symmetry Consider: take Ising configuration {η i }, and η i(α,β) τ ατ β η i(α,β) with τ α = ±1 arbitrarily (for every diamond site α.) Matrix µ = τ µτ 1, is similarity transformation. Same eigenvalues same E harm. Explains why H eff harm had form of gauge model. Large [exp(constl)] degeneracy! Gauge-like only: still must satisfy ground-state condition η i = 0, (each tetrahedron ). i α 14
15 Ground-state degeneracy Any collinear classical ground state with spin product i η i = 1 around every hexagon is a degenerate ground state. Called π-flux state The smallest magnetic unit cell has 16 spins. The residual entropy is at least O(L) and at most O(L ln L) 32 spin cell z=0 z=1/2 ν = 1 z=0 z=1/2 ν =+1 z=3/4 z=1/4 z=3/4 z=1/4 15
16 2. Quartic (self-cons.) spin-waves Holstein-Primakoff transformation/expansion Relate standard bosons to spin deviation operators: a i = (η i σ x i + iσy i )/ 2S. Hamiltonian: classical + harmonic + quartic H = JN s S 2 ( + J ) σ i 2 + J 2S + J 4S 2 ij i ( ) 2 σ i σ j 4S ij ( η i η j σ i 2 σ j σ i σ j ( σi 2 + σ j 2)) + O(S 1 ). (Harmonic term which gave E harm depends on {η i } via [σ x i, σy j ] = iη isδ ij ) 16
17 Self-consistent decoupling (standard) Mean-field Hamiltonian: as if modify bonds δj ij = 1 [ 1 ( σ 2 2S 2 2 i + σ 2 j ) ] η i η j σ i σ j Numerically: dominated by divergent modes (with hω m = 0). Consider only harmonic ground ( π-flux ) states: totally uniform in space (for harmonic=gauge-invariant properties). Symmetry σ i σ j depends only on η i η j δj ij = ɛ 8 η iη j with ɛ = O(ln S/S) [from integrate across divergence in B.Z.] 17
18 Effective Hamiltonian for quartic energy Most of anharmonic energy is actually gauge -invariant Effective Hamiltonian that splits harmonic states: H eff quart = C 6 (S)P 6 + C 8 (S)P , where P 2l = no. AFM (...) loops of length 2l; Obtained from empirical fit (first!) Lead term (P 6 ) derived (later!) by inserting δj ij = (...)ɛη i η j into loop expansion from harmonic calculation. Energy scale C 2l (S) = O(ln S 2 ). Ground state(s) our grand answer but complicated/unclear: Independent slabs, 2 choices/slab, alternately a/2 or a/4 thick Degenerate (?) entropy = O(L)? I think not, but shortest loop that might split them is length 26(!) 18
19 Numerical check Using database of many π-flux (harmonic ground states) 19
20 3. Large-N approach to large-s limit with: Dr. Prashant Sharma Motivation for large N approach [U. Hizi, P. Sharma, and C. L. Henley, PRL 2005] Another systematic approach beyond classical/harmonic level Generalized spins with Sp(N) symmetry [Physical: Sp(1) = SU(2)]. Can solve N exactly. [Read & Sachdev, 1989] N flavors of boson; representation labeled by κ (generalizes 2S). Usual: small κ to approximate S = 1/2 Ours: large κ breaks degeneracies at lowest nontrivial order (first nontrivial term in 1/κ expansion) 20
21 Set-up: Large-N mean field theory Spin operators: bilinear in boson operators b iσm, b iσm [ σ =, ; flavor m = 1,..., N] Exchange interaction: bilinear in valence bond operators ˆQ ij b i,m b j,m b i,m b j,m. Decoupling gives H Sp(N) = 1 2 ij ( ) N Q ij 2 + Q ij ˆQij + H.c. + i λ i ( ˆN b i ) Nκ with classical coeff. Q ij ˆQ ij /N (self-consistent). Lagrange multipliers λ i 4κ (every i): enforce κ bosons, each site Ordered state: has b iσ,m 0. 21
22 Trace expansion for large-n case Bogoliubov diagonalization zero-point energy is E Sp(N) ({Q ij }) = N 2 [Tr λ 2 Q Q N s λ] If a collinear type ordered state: Q ij = κ(η i η j )/2 [= 0 or ± κ]. Expand trace as previous cases! Different matrix (only connects on satisfied bonds) Different lattice (pyrochlore trivial loops on 1 tetrahedron) 22
23 Effective Hamiltonian for large N case Real-space expansion in loops of valence bonds: H eff Sp(N) = Nκ 2 ( N spins P P 8 + ) [As in quartic. P 2l no. AFM loops (...) of length 2l.] Numerical check with general collinear ground states 23
24 Ground states for large N? Monte Carlo simulate H eff Sp(N) ( 3456 sites): hunt ground states. nearly degenerate stacks of layers (alternate a/4, a/2 thick) Splitting 10 7 per spin (from length 2l = 16 loops) unique ground state (96 site cell). Oops! 1/N expansion gave wrong answer! Harmonic term of 1/S expansion must dominate at S 1 Physical (SU(2)) ground state must be π-flux state. ground states of H eff Sp(N) are not π-flux states. Among π-flux states, P 6 term does agree with H eff quart. 24
25 4. Conclusions: summary/discussion Key tricks used: Get configuration labels as coefficients (in matrix) Zero-point energy in terms of trace [(matrix) 2 ] Common features between harmonic/quartic/large-n calculations: Effective Hamiltonian as loop sum E harm /S (a) (b) eff /S H harm E quart eff H quart E Sp(N) /NS (c) eff H Sp(N) /NS Degenerate (or nearly) states, entropy O(L) (non extensive). Practically: Energy differences too small to be seen experimentally. 25
26 Discussion Details surprisingly unlike Kagomé case [E. P. Chan & CLH, 1994] Kagomé: always ˆn i ˆn j = 1/2 all coplanar states degenerate (extensive entropy) at harmonic order. Kagomé: zonefull of divergent modes E anh = O(S 2/3 ) Applicable to other systems checkerboard (planar pyrochlore) confirm known answers Field plateau states (e.g. pyrochlore collinear ) (harmonic: opposite sign for loop product, η i = +1.) Will addition of tunneling give spin-disordered superposition? No! O(L) ground state entropy must flip O(L 2 ) spins tunnel amplitude exponentially small. Will work in kagomé case. [See von Delft & Henley PRB 1993] 26
27 Disc. details 1: Comparison to Kagomé case Kagomé Pyrochlore 1. Spin order Coplanar Collinear 2. Symmetry between No (in-plane Yes deviation components and out-of-plane) (x and y) 3. Divergent modes entire zone Along lines in q space 4. Anharm. E scale S 2/3 (ln S) 2 5. Neighbor spin angles 2π/3 0 or π 6. H harm gr. st. degen.? all O(L) entropy 7. Anharmonic terms H cubic + H quart H cubic =0 8. H eff interactions nonlocal local 27
28 Discussion details 2: Other systems (1) Harmonic H eff harm: checkerboard (planar pyrochlore) lattice [Done by Tchernyshyov-Starykh-Moessner-Abanov PRB 2003] field plateaus (kagomé, pyrochlore ) (Opposite sign for loop product of Ising spins!) (2) Quartic H eff quart: checkerboard lattice [But lattice already breaks symmetry.] field plateaus (see list above): undone (3) Large-N H eff Sp(N): checkerboard lattice [same answer as Bernier et al PRB 2004] Kagomé lattice [same answer as Sachdev PRB 1992] 28
29 Disc. details 3: disordered superpositions?? Just add to effective Hamiltonian the off-diagonal terms, representing tunneling between collinear states? [See von Delft & Henley PRB 1993, kagomé; see Bergman et al, nearly-ising pyrochlore at mag. plateau] Expect, if diagonal terms (i.e. H eff ) tunneling amplitudes. The extra terms are ring-exchanges [like Hermele et al, 2004] Mixture would be quantum spin nematic. But no!: O(L) ground state entropy need to flip O(L 2 ) spins tunnel amplitude exponentially small. Try kagomé lattice (or garnet lattice 3D!) built from triangles: there, harmonic-order ground states with extensive entropy. 29
30 Disc. details 1 v2: comparison to kagome System // Kagomé // Pyrochlore There, spin-wave fluctuations selected 1. Zero-order selection // // coplanar // collinear 2. Divergent modes in Brilouin zone ( 1) // whole zone // (100) lines in zone 3. Scaling of anharmonic H eff [harmonic was O(S)]( 2) // O(S 2/3 ) // O([log S] 2 ) 4. Neighbor spin angles // 2π/3 // 0 or π 5. Harmonic order ground state entropy ( 4) // extensive // O(L) (of L 3 ) 6. Anharmonic spinwave H terms, in deviations σ x,y ( 1) // O(σ 3 ) + O(σ 4 ) // O(σ 4 ) // 7. Effective spin interactions ( 6) // long-range // short-range 30
31 Disc. 2: Ot. systems (S: checkerboard+) Harmonic easily applied to ot. models w/ tetrahedra : 1. The checkerboard lattice: The zero-flux states are degenerate harmonic ground states. Tchernyshyov et al., PRB 68, (2003) The entropy is O(L). The anharmonic ground state is the (π, π) state. 31
32 2. The capped-kagomé lattice: The 2 2 states are degenerate harmonic ground states. Tchernyshyov et al., PRB 69, (2004) The effective Hamiltonian s terms compete with each other, and the 2 2 narrowly wins over other states. The entropy is extensive. 32
33 Disc. 2: Other systems (Suppl: plateau) The theory can also be modified to apply to collinear states with non-zero magnetization M in each simplex: The M = 2 pyrochlore model s ground states are the zero-flux states and the entropy is at least of order L. The M = 2 checkerboard model has π-flux states as ground states, with entropy of order L. The M = 1 kagomé model has zero-flux states as ground states, and the entropy is O(L). 33
34 Harmonic spin-waves: Dispersion (supplementary U.H.) In Fourier space, half of the bands are generically zero modes, and half are ordinary bands. 4 S Ω q Some of the ordinary bands frequencies go to zero along the entire x, y, or z axes. Π Π q x 0 Π 2 Π Π Π Π 2 0q y Π 2 q y log(<σ i 2 >) for qz = q x q z log(<σ i 2 >) for qy = q x The zero-frequency eigenmodes along these lines have divergent fluctuations σ q σ q. 34
35 Spin-wave Divergent modes (suppl.) The divergent modes dominate the fluctuations, and will dominate the anharmonic spin-wave theory. Divergent modes are modes, in real space: Are zero modes: i α v(i) = 0. Are eigenmodes of the diamond lattice Hamiltonian v = ηw T u. Can be separated into two linear subspaces, living on even and odd tetrahedra only, so that v(i) = η i u(α(i)). One can construct a basis so that u(α) = ±1 for every diamond lattice site on a quasi-twodimensional support network. 35
36 Divergent fluctuations in harmonic oscillator Consider simple harmonic oscillator: H = k 2 x m p2, [x, p] = i h. Equations of motion: ẋ = ī h [x, H] = 1 m p, ṗ = ī [p, H] = kx. h Solving equations of motion, we obtain ω = k/m. The quantum fluctuations of the conjugate operators x, p are: x 2 1 mk, p 2 mk. As k goes to zero, fluctuations in x diverge! 36
37 Harmonic: Gaugelike transformation (suppl.) Aim: Flip four spins in a tetrahedron for a set of tetrahedra, so that the classical constraint i α η i = 0 is conserved. If we flip one even tetrahedron, then its neighboring odd tetrahedra violate the tetrahedron constraint. Need to flip a network of even tetrahedra to get a valid even transformation. Any gaugelike transformation can be expressed as a product of an even transformation and an odd transformation: τ = τ even τ odd. 37
38 Harmonic ground states (supplementary) Some example states: [Bonds are shown black or blue depending whether they are FM or AFM.] 38
39 Quartic: Divergent modes (suppl.) Divergent modes: where ordinary modes ( diamond lattice) become linearly dependent with generic zero modes (related to continuous degeneracies). π-flux states states totally uniform (gauge-inv. prop s). Divergent fluctuations are practically gaugelike-invariant. It turns out this implies σ i σ j takes two values, differing by C 2 (ɛ) (depending whether ij bond is FM or AFM), and δj ij = const(ɛ) ɛ 8 η iη j with small parameter ɛ = C 2 (ɛ)/2s 2. C 2 (ɛ) S ln ɛ. (from integrating modes over reciprocal space: anisotropic momentum dependence near divergence lines.) ɛ ln S/S; Quartic energy E quart (ln S) 2 ). 39
40 Quartic spin-waves (supplementary): S dependence Formula for quartic energy: E quart = H 2 + H 4 Ψvar = 2 i Here G ij 1 2 σ i σ j. G ii + 2 ij G ij S 2 ij ( [ ηi η j Gii G jj + G 2 ] ij (Gii + G jj ) We diagonalize the mean-field Hamiltonian to find variational wavefunction and correlations σi xσx j ), and plugged into the quartic energy expectation, E quart ; note that (apart from a factor of 1/2) it is same as the expectation of mean-field Hamiltonian, treated as if harmonic. Now minimize w.r.t. ɛ (for a given S); mathematically equivalent to enforcing self-consistency (but harder, oops!). 40
41 Quartic (supplementary) Numerics We first calculated E quart for several collinear classical ground states. E quart = O((ln S) 2 ), leading order contribution is apparently gauge-invariant. E quart E MF /S S S 0 flux π flux 000π planes 0π0π planes 00ππ planes E quart Focusing in on a set of 12 harmonic ground states (π-flux states), we see that the harmonic order degeneracy is broken S 41
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