Dark state

In atomic physics, a dark state refers to a state of an atom or molecule that cannot absorb (or emit) photons. All atoms and molecules are described by quantum states; different states can have different energies and a system can make a transition from one energy level to another by emitting or absorbing one or more photons. However, not all transitions between arbitrary states are allowed. A state that cannot absorb an incident photon is called a dark state. This can occur in experiments using laser light to induce transitions between energy levels, when atoms can spontaneously decay into a state that is not coupled to any other level by the laser light, preventing the atom from absorbing or emitting light from that state. In atomic physics, a dark state refers to a state of an atom or molecule that cannot absorb (or emit) photons. All atoms and molecules are described by quantum states; different states can have different energies and a system can make a transition from one energy level to another by emitting or absorbing one or more photons. However, not all transitions between arbitrary states are allowed. A state that cannot absorb an incident photon is called a dark state. This can occur in experiments using laser light to induce transitions between energy levels, when atoms can spontaneously decay into a state that is not coupled to any other level by the laser light, preventing the atom from absorbing or emitting light from that state. A dark state can also be the result of quantum interference in a three-level system, when an atom is in a coherent superposition of two states, both of which are coupled by lasers at the right frequency to a third state. With the system in a particular superposition of the two states, the system can be made dark to both lasers as the probability of absorbing a photon goes to 0. Experiments in atomic physics are often done with a laser of a specific frequency ω {displaystyle omega } (meaning the photons have a specific energy), so they only couple one set of states with a particular energy E 1 {displaystyle E_{1}} to another set of states with an energy E 2 = E 1 + ℏ ω {displaystyle E_{2}=E_{1}+hbar omega } . However, the atom can still decay spontaneously into a third state by emitting a photon of a different frequency. The new state with energy E 3 < E 2 {displaystyle E_{3}<E_{2}} of the atom no longer interacts with the laser simply because no photons of the right frequency are present to induce a transition to a different level. In practice, the term dark state is often used for a state that is not accessible by the specific laser in use even though transitions from this state are in principle allowed. Whether or not we say a transition between a state | 1 ⟩ {displaystyle |1 angle } and a state | 2 ⟩ {displaystyle |2 angle } is allowed often depends on how detailed the model is that we use for the atom-light interaction. From a particular model follow a set of selection rules that determine which transitions are allowed and which are not. Often these selection rules can be boiled down to conservation of angular momentum (the photon has angular momentum). In most cases we only consider an atom interacting with the electric dipole field of the photon. Then some transitions are not allowed at all, others are only allowed for photons of a certain polarization. Consider for example the hydrogen atom. The transition from the state 1 2 S 1 / 2 {displaystyle 1^{2}S_{1/2}} with mj=-1/2 to the state 2 2 P 3 / 2 {displaystyle 2^{2}P_{3/2}} with mj=-1/2 is only allowed for light with polarization along the z axis (quantization axis) of the atom. The state 2 2 P 3 / 2 {displaystyle 2^{2}P_{3/2}} with mj=-1/2 therefore appears dark for light of other polarizations.Transitions from the 2S level to the 1S level are not allowed at all. The 2S state can not decay to the ground state by emitting a single photon. It can only decay by collisions with other atoms or by emitting multiple photons. Since these events are rare, the atom can remain in this excited state for a very long time, such an excited state is called a metastable state. We start with a three-state Λ-type system, where | 1 ⟩ ↔ | 3 ⟩ {displaystyle |1 angle leftrightarrow |3 angle } and | 2 ⟩ ↔ | 3 ⟩ {displaystyle |2 angle leftrightarrow |3 angle } are dipole-allowed transitions and | 1 ⟩ ↔ | 2 ⟩ {displaystyle |1 angle leftrightarrow |2 angle } is forbidden. In the rotating wave approximation, the semi-classical Hamiltonian is given by