Qutrit

Template:Short description Template:Fundamental info units A qutrit (or quantum trit) is a unit of quantum information that is realized by a 3-level quantum system, that may be in a superposition of three mutually orthogonal quantum states.^[1]

The qutrit is analogous to the classical radix-3 trit, just as the qubit, a quantum system described by a superposition of two orthogonal states, is analogous to the classical radix-2 bit.

There is ongoing work to develop quantum computers using qutrits^[2][3][4] and qudits in general.^[5][6][7]

Representation

A qutrit has three orthonormal basis states or vectors, often denoted ${\displaystyle |0⟩}$, ${\displaystyle |1⟩}$, and ${\displaystyle |2⟩}$ in Dirac or bra–ket notation. These are used to describe the qutrit as a superposition state vector in the form of a linear combination of the three orthonormal basis states:

${\displaystyle |\psi ⟩=\alpha |0⟩+\beta |1⟩+\gamma |2⟩}$,

where the coefficients are complex probability amplitudes, such that the sum of their squares is unity (normalization):

${\displaystyle |\alpha {|}^2+|\beta {|}^2+|\gamma {|}^2=1}$

The qubit's orthonormal basis states ${\displaystyle \{|0⟩,|1⟩\}}$ span the two-dimensional complex Hilbert space ${\displaystyle H_2}$, corresponding to spin-up and spin-down of a spin-1/2 particle. Qutrits require a Hilbert space of higher dimension, namely the three-dimensional ${\displaystyle H_3}$ spanned by the qutrit's basis ${\displaystyle \{|0⟩,|1⟩,|2⟩\}}$,^[8] which can be realized by a three-level quantum system.

An n-qutrit register can represent 3ⁿ different states simultaneously, i.e., a superposition state vector in 3ⁿ-dimensional complex Hilbert space.^[9]

Qutrits have several peculiar features when used for storing quantum information. For example, they are more robust to decoherence under certain environmental interactions.^[10] In reality, manipulating qutrits directly might be tricky, and one way to do that is by using an entanglement with a qubit.^[11]

Qutrit quantum gates

The quantum logic gates operating on single qutrits are ${\displaystyle 3\times 3}$ unitary matrices and gates that act on registers of ${\displaystyle n}$ qutrits are ${\displaystyle 3^n\times 3^n}$ unitary matrices (the elements of the unitary groups U(3) and U(3ⁿ) respectively).^[12]

The rotation operator gatesTemplate:Efn for SU(3) are ${\displaystyle \mathrm{Rot}({\mathrm{\Theta }}_1,{\mathrm{\Theta }}_2,\dots ,{\mathrm{\Theta }}_8)=\exp (-i{\displaystyle \sum _{a=1}^8}{\mathrm{\Theta }}_a\frac{{\lambda }_a}{2})}$, where ${\displaystyle {\lambda }_a}$ is the aTemplate:'th Gell-Mann matrix, and ${\displaystyle {\mathrm{\Theta }}_a}$ is a real value. The Lie algebra of the matrix exponential is provided here. The same rotation operators are used for gluon interactions, where the three basis states are the three colors (${\displaystyle |0⟩=\text{red},|1⟩=\text{green},|2⟩=\text{blue}}$) of the strong interaction.^[13][14]Template:Efn

The global phase shift gate for the qutritTemplate:Efn is ${\displaystyle \mathrm{Ph}(\delta )=\left[\begin{array}{ccc}{e}^{i\delta }& 0& 0\\ 0& e^{i\delta }& 0\\ 0& 0& e^{i\delta }\end{array}\right]=\exp \left(i\delta I\right)=e^{i\delta }I}$ where the phase factor ${\displaystyle e^{i\delta }}$ is called the global phase.

This phase gate performs the mapping ${\displaystyle |\mathrm{\Psi }⟩\mapsto e^{i\delta }|\mathrm{\Psi }⟩}$ and together with the 8 rotation operators is capable of expressing any single-qutrit gate in U(3), as a series circuit of at most 9 gates.

See also

• Gell-Mann matrices
• Generalizations of Pauli matrices
• Mutually unbiased bases
• Quantum computing
• Radix economy
• Ternary computing

Notes

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References

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External links

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