Polarizability by linear response
We compute the polarizability of a Helium atom. The polarizability is defined as the change in dipole moment
\[μ = ∫ r ρ(r) dr\]
with respect to a small uniform electric field $E = -x$.
We compute this in two ways: first by finite differences (applying a finite electric field), then by linear response. Note that DFTK is not really adapted to isolated atoms because it uses periodic boundary conditions. Nevertheless we can simply embed the Helium atom in a large enough box (although this is computationally wasteful).
As in other tests, this is not fully converged, convergence parameters were simply selected for fast execution on CI,
using DFTK
using LinearAlgebra
using PseudoPotentialData
a = 10.
lattice = a * I(3) # cube of ``a`` bohrs
pseudopotentials = PseudoFamily("cp2k.nc.sr.lda.v0_1.largecore.gth")
# Helium at the center of the box
atoms = [ElementPsp(:He, pseudopotentials)]
positions = [[1/2, 1/2, 1/2]]
kgrid = [1, 1, 1] # no k-point sampling for an isolated system
Ecut = 30
tol = 1e-8
# dipole moment of a given density (assuming the current geometry)
function dipole(basis, ρ)
rr = [(r[1] - a/2) for r in r_vectors_cart(basis)]
sum(rr .* ρ) * basis.dvol
end;Using finite differences
We first compute the polarizability by finite differences. First compute the dipole moment at rest:
model = model_DFT(lattice, atoms, positions;
functionals=LDA(), symmetries=false)
basis = PlaneWaveBasis(model; Ecut, kgrid)
scfres = self_consistent_field(basis; tol)
μref = dipole(basis, scfres.ρ)-0.0001345739188649197Then in a small uniform field:
ε = .01
model_ε = model_DFT(lattice, atoms, positions;
functionals=LDA(),
extra_terms=[ExternalFromReal(r -> -ε * (r[1] - a/2))],
symmetries=false)
basis_ε = PlaneWaveBasis(model_ε; Ecut, kgrid)
res_ε = self_consistent_field(basis_ε; tol)
με = dipole(basis_ε, res_ε.ρ)0.0176122203751195polarizability = (με - μref) / ε
println("Reference dipole: $μref")
println("Displaced dipole: $με")
println("Polarizability : $polarizability")Reference dipole: -0.0001345739188649197
Displaced dipole: 0.0176122203751195
Polarizability : 1.774679429398442
The result on more converged grids is very close to published results. For example DOI 10.1039/C8CP03569E quotes 1.65 with LSDA and 1.38 with CCSD(T).
Using linear response
Now we use linear response (also known as density-functional perturbation theory) to compute this analytically; we refer to standard textbooks for the formalism. In the following, $χ_0$ is the independent-particle polarizability, and $K$ the Hartree-exchange-correlation kernel. We denote with $δV_{\rm ext}$ an external perturbing potential (like in this case the uniform electric field).
# `δVext` is the potential from a uniform field interacting with the dielectric dipole
# of the density.
δVext = [-(r[1] - a/2) for r in r_vectors_cart(basis)]
δVext = cat(δVext; dims=4);
nothing # hideThen:
\[δρ = χ_0 δV = χ_0 (δV_{\rm ext} + K δρ),\]
which implies
\[δρ = (1-χ_0 K)^{-1} χ_0 δV_{\rm ext}.\]
From this we identify the polarizability operator to be $χ = (1-χ_0 K)^{-1} χ_0$. Numerically, we apply $χ$ to $δV = -x$ by solving a linear equation (the Dyson equation) iteratively.
First we do this using the DFTK.solve_ΩplusK_split function provided by DFTK, which uses an adaptive Krylov subspace algorithm [HS2025]:
# Multiply δVext times the Bloch waves, then solve the Dyson equation:
δVψ = DFTK.multiply_ψ_by_blochwave(scfres.basis, scfres.ψ, δVext)
res = DFTK.solve_ΩplusK_split(scfres, δVψ; verbose=true);
nothing # hideIter Restart Krydim log10(res) avg(CG) Δtime Comment
---- ------- ------ ---------- ------- ------ ---------------
13.0 63.7ms Non-interacting
1 0 1 -0.60 10.0 7.64s
2 0 2 -2.42 7.0 110ms
3 0 3 -3.54 5.0 139ms
4 0 4 -5.33 4.0 96.8ms
5 0 5 -7.59 1.0 104ms
6 0 6 -10.30 1.0 84.9ms
7 1 1 -7.43 13.0 221ms Restart
8 1 2 -8.94 1.0 91.4ms
12.0 125ms Final orbitals
From the result of solve_ΩplusK_split we can easily compute the polarisabilities:
println("Non-interacting polarizability: $(dipole(basis, res.δρ0))")
println("Interacting polarizability: $(dipole(basis, res.δρ))")Non-interacting polarizability: 1.925712532097341
Interacting polarizability: 1.7736548622691026
As expected, the interacting polarizability matches the finite difference result. The non-interacting polarizability is higher.
Manual solution of the Dyson equations
To see what goes on under the hood, we also show how to manually solve the Dyson equation using KrylovKit:
using KrylovKit
# Apply ``(1- χ_0 K)``
function dielectric_operator(δρ)
δV = apply_kernel(basis, δρ; scfres.ρ)
χ0δV = apply_χ0(scfres, δV).δρ
δρ - χ0δV
end
# Apply ``χ_0`` once to get non-interacting dipole
δρ_nointeract = apply_χ0(scfres, δVext).δρ
# Solve Dyson equation to get interacting dipole
δρ = linsolve(dielectric_operator, δρ_nointeract, verbosity=3)[1]
println("Non-interacting polarizability: $(dipole(basis, δρ_nointeract))")
println("Interacting polarizability: $(dipole(basis, δρ))")[ Info: GMRES linsolve starts with norm of residual = 4.19e+00
[ Info: GMRES linsolve in iteration 1; step 1: normres = 2.49e-01
[ Info: GMRES linsolve in iteration 1; step 2: normres = 3.77e-03
[ Info: GMRES linsolve in iteration 1; step 3: normres = 2.85e-04
[ Info: GMRES linsolve in iteration 1; step 4: normres = 4.69e-06
[ Info: GMRES linsolve in iteration 1; step 5: normres = 1.09e-08
[ Info: GMRES linsolve in iteration 1; step 6: normres = 6.27e-11
[ Info: GMRES linsolve in iteration 1; step 7: normres = 1.13e-08
[ Info: GMRES linsolve in iteration 2; step 1: normres = 9.89e-10
[ Info: GMRES linsolve in iteration 2; step 2: normres = 3.33e-11
┌ Info: GMRES linsolve converged at iteration 2, step 3:
│ * norm of residual = 3.87e-12
└ * number of operations = 12
Non-interacting polarizability: 1.9257125320972812
Interacting polarizability: 1.773654861776565
We obtain the identical result to above.
- HS2025M. F. Herbst and B. Sun. Efficient Krylov methods for linear response in plane-wave electronic structure calculations. arXiv 2505.02319