Precise creation, characterization and manipulation of single optical qubits

Nicholas Peters; Joseph Altepeter; Evan Jeffrey; David Branning; Paul Kwiat

Precise creation, characterization and manipulation of single optical qubits

Nicholas Peters
, Joseph Altepeter
, Evan Jeffrey
, David Branning
, Paul Kwiat

Research output: Contribution to journal › Article › peer-review

33 Scopus citations

Abstract

We present the theoretical basis for and experimental verification of arbitrary single-qubit state generation, using the polarization of photons generated via spontaneous parametric downconversion. Our precision measurement and state reconstruction system has the capability to distinguish over 3 million states, all of which can be reproducibly generated using our state creation apparatus. In order to complete the triumvirate of single qubit control, there must be a way to not only manipulate single qubits after creation and before measurement, but a way to characterize the manipulations themselves. We present a general representation of arbitrary processes, and experimental techniques for generating a variety of single qubit manipulations, including unitary, decohering, and (partially) polarizing operations.

Original language	English
Pages (from-to)	503-517
Number of pages	15
Journal	Quantum Information and Computation
Volume	3
Issue number	SPEC. ISS.
State	Published - Oct 2003
Externally published	Yes

Keywords

Parametric down-conversion
Photon polarization
Quantum process
Qubit
Tomography

Cite this

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title = "Precise creation, characterization and manipulation of single optical qubits",

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AU - Peters, Nicholas

AU - Altepeter, Joseph

AU - Jeffrey, Evan

AU - Branning, David

AU - Kwiat, Paul

PY - 2003/10

Y1 - 2003/10

N2 - We present the theoretical basis for and experimental verification of arbitrary single-qubit state generation, using the polarization of photons generated via spontaneous parametric downconversion. Our precision measurement and state reconstruction system has the capability to distinguish over 3 million states, all of which can be reproducibly generated using our state creation apparatus. In order to complete the triumvirate of single qubit control, there must be a way to not only manipulate single qubits after creation and before measurement, but a way to characterize the manipulations themselves. We present a general representation of arbitrary processes, and experimental techniques for generating a variety of single qubit manipulations, including unitary, decohering, and (partially) polarizing operations.

AB - We present the theoretical basis for and experimental verification of arbitrary single-qubit state generation, using the polarization of photons generated via spontaneous parametric downconversion. Our precision measurement and state reconstruction system has the capability to distinguish over 3 million states, all of which can be reproducibly generated using our state creation apparatus. In order to complete the triumvirate of single qubit control, there must be a way to not only manipulate single qubits after creation and before measurement, but a way to characterize the manipulations themselves. We present a general representation of arbitrary processes, and experimental techniques for generating a variety of single qubit manipulations, including unitary, decohering, and (partially) polarizing operations.

KW - Parametric down-conversion

KW - Photon polarization

KW - Quantum process

KW - Qubit

KW - Tomography

UR - https://www.scopus.com/pages/publications/2342467162

M3 - Article

AN - SCOPUS:2342467162

SN - 1533-7146

VL - 3

SP - 503

EP - 517

JO - Quantum Information and Computation

JF - Quantum Information and Computation

IS - SPEC. ISS.

ER -

Precise creation, characterization and manipulation of single optical qubits

Abstract

Keywords

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