Introduction

Bose-Einstein theory describes the behaviour of integer spin objects (bosons). This theory predicted the so-called Bose-Einstein Condensation (BEC) phenomenon. Bose Einstein condensates is one of exotic ground states in strongly correlated systems. At first, this condensation concept was applied to dilute gases of bosons which are weakly interacting. Those gases were confined in an external potential and cooled to temperatures very near to absolute zero. These cooling bosonic atoms then fall (or "condensate") into the lowest accessible quantum state, resulting in a new form of matter. One example of these gases is helium-3.

Not long after the aplications of Bose and Einstein statistics to photons and atoms, Bloch applied the same concept to excitations in solid. He explained that the state of misaligned spins in a ferromagnet can be regarded as magnons, quasiparticles with integer spin and bosonic statistics. In 1965 paper, Matsubara and Matsuda pointed out the correpondences between a quantum ferromagnet and a lattice Bose gas ^[1].

The similarity between the Bose gases and magnons suggests that magnons can undergo a process like Bose-Einstein condensation. However, in this case we are only considering simple spin systems, if we want to assume more realistic cases, such factors like anisotropies could restrict the usefulness of BEC concept.

Nevertheless, the analogy between bosons and spins has been very useful in antiferromagnetic systems which closely spaced pairs of spins ${\displaystyle S={1 \over 2}}$ form with a singlet ${\displaystyle S=0}$ ground state and triplet ${\displaystyle S=1}$ excitations called magnons (some people call them triplons). Some examples of this system are ${\displaystyle TlCuCl_{3}}$ and ${\displaystyle BaCuSi_{2}O_{6}\$}$.

Here I present an overview of BEC in antiferromagnetic systems.

Bosons in Magnets

In this part we will explain the basics of magnon BEC in real dimerized antiferromagnets, such as ${\displaystyle TlCuCl_{3}}$ and $BaCuSi_2O_6$. The lattice of magnetic ions can be regarded as a set of dimers carrying ${\displaystyle S={1 \over 2}}$ each. We assume the Hamiltonian is in the form ^[2].

${\displaystyle \mathbf {H} =\sum _{i}J_{0}\,\mathbf {S} _{1,i}\cdot \mathbf {S} _{2,i}+\sum _{\langle mnij\rangle }J_{mnij}\,\mathbf {S} _{m,i}\cdot \mathbf {S} _{n,j}-g\mu _{B}H\sum _{\langle mi\rangle }S_{m,i}^{z},}$\quad\quad\quad (1)