Entanglement and Bell’s inequality violation above room temperature in metal carboxylates

Souza, Alexandre M.; Soares-Pinto, Diogo O.; Sarthour, R. S.; Oliveira, I. S.; Reis, M. S.; Brandão, Paula; Santos, A. M. dos

doi:10.1103/physrevb.79.054408

Cited by 48 publications

(57 citation statements)

References 36 publications

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“…Algoritmos baseados nas propriedades do Mn12Ac já foram propostos, assim como a existência de estados quanticamente emaranhados. 101 Um grande esforço tem sido feito no desenvolvimento da tecnologia de manipulação de spins, como a técnica de ressonância paramagnética eletrônica pulsada, para aplicação futura em dispositivos para computação quântica. 4 …”

Section: Perspectivas De Aplicação De Smmunclassified

Compostos magnéticos moleculares: o desenvolvimento de novos materiais magnéticos nanoestruturados

Guedes¹,

Allão²,

Mercante³

et al. 2010

Quím. Nova

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Recebido em 7/11/09; aceito em 21/4/10; publicado na web em 9/8/10 MOLECULAR MAGNETIC COMPOUNDS -THE DEVELOPMENT OF NEW NANOSTRUTURED MAGNETIC MATERIALS. The development of new magnetic materials has attracted attention of researchers of different areas. In the last decades, a distinguished class of materials emerged in magnetism, in which the magnetic moment is delocalized over molecules. By varying the synthetic conditions it is possible to obtain a large variety of structures and properties using the same starting molecules. These materials have a great scientific appeal due to the possibility of presenting not only magnetic, but also optical or electrical transport properties. In this review we will present an overview of some molecular magnetic compounds, in particular molecular nanomagnets.Keywords: molecular magnetic compounds; deposition on surfaces; magnetic materials. INTRODUÇÃOO magnetismo molecular é uma área de pesquisa interdisciplinar relativamente nova que pode ser considerada uma evolução da magnetoquímica.1 As possibilidades de atuação neste tema são amplas e pesquisadores de diversas especialidades estão trabalhando cada vez mais em conjunto. Esta interação envolve sínteses orgânica e inorgânica e o uso de técnicas de caracaterização magnética, difração de raios-x, eletroquímica e espectroscopias diversas, entre outras técnicas. Um dos objetivos é compreender a origem das propriedades magnéticas, sendo uma área que apresenta grandes desafios também para pesquisadores que fazem cálculos, envolvendo desde a simulação de dados experimentais até cálculos mais elaborados de modelagem molecular e energia dos sistemas possibilitando fazer correlações magneto-estruturais. 2Esta interdisciplinaridade tem possibilitado a descoberta e o entendimento de novos fenômenos como o tunelamento quântico da magnetização, coerência e emaranhamento quântico, que são fundamentais para aplicações na área de computação quântica. Além disso, outro grande atrativo é que estes materiais moleculares podem apresentar sinergia entre propriedades magnéticas, condutoras e ópticas, o que é interessante para aplicações tecnológicas. 4 Neste artigo de revisão são apresentadas algumas das diversas estratégias utilizadas na síntese de compostos magnéticos moleculares. Também será abordado o progresso na obtenção e deposição em superfícies de um dos sistemas mais interessantes da área, os chamados magnetos de uma molécula ou nanomagnetos moleculares. Esta é uma etapa de extrema importância que visa a formação de sistemas magnéticos nanoestruturados para aplicação em dispositivos. COMPOSTOS MAGNÉTICOS MOLECULARES PURAMENTE ORGÂNICOSMoléculas orgânicas paramagnéticas são conhecidas por apresentarem alta reatividade, além de não serem estáveis termicamente. No entanto, certas classes de radicais orgânicos apresentam estabilidade à temperatura ambiente e relativa facilidade sintética, o que vêm fascinando químicos e físicos pela variedade de propriedades magnéticas, ópticas e condutoras que podem exibir. 5O estudo das propriedades magn...

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Section: Perspectivas De Aplicação De Smmunclassified

Compostos magnéticos moleculares: o desenvolvimento de novos materiais magnéticos nanoestruturados

Guedes¹,

Allão²,

Mercante³

et al. 2010

Quím. Nova

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Section: Abstract: Quantum Discord Geometric Correlations Molecularmentioning

confidence: 99%

“…They combine classical properties, found in any macroscopic magnet, with quantum ones, such as quantum interference and entanglement. The large gap between the ground state and the first-excited state found in some materials allows the existence of entangled quantum states at higher temperatures [6,11,13,17]. The study of molecular magnets opens thus doors for new research toward to the limits of quantum mechanics; and several aspects are worthy of a thorough research, such as (i) how robust their quantum features are against temperature and (ii) how large systems can support these properties.…”

mentioning

confidence: 99%

“…In spite of that, it is fragile and can easily vanish due to the inevitable interaction of the system with its environment [4]; and due to this condition, it was thought that entanglement could only exist at low temperatures. However, recently, it has been shown that entanglement can also exist at higher temperatures, and can be detected through the measurement of some thermodynamic observables [5][6][7][8][9][10][11][12][13][14][15][16][17].Nevertheless, quantum entanglement does not encompass all quantum correlations in a system and recent studies have greatly expanded the notion of quantum correlations [18][19][20][21][22][23][24][25][26][27][28][29]; and the measure of quantum excess of correlations has been named as quantum discord [19][20][21]. In the last years, it was understood that quantum discord has an important role in many quantum information processing even without entanglement.…”

mentioning

confidence: 99%

“…The quantum properties of several materials have been deeply analyzing by means of thermodynamic quantities [5][6][7][8][9][10][11][12][13][14][15][16][17], and magnetic susceptibility χ has been a good benchmark [5-8, 10-13, 17] due to the easy experimental access. For the material under consideration, the experimental χT quantity, for the whole range of temperature considered (<300 K), is smaller than the Curie constant of the dimer C = 1.34 × 10 −4 µ B K/FU-Oe; and it is a clear signature that at least one exchange interactions into the system is larger than the thermal energy at room temperature.…”

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confidence: 99%

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Carboxylate-based molecular magnet: One path toward achieving stable quantum correlations at room temperature

Cruz¹,

Soares-Pinto²,

Brandão³

et al. 2016

EPL

Self Cite

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The control of quantum correlations in solid state systems by means of material engineering is a broad avenue to be explored, since it makes possible steps toward the limits of quantum mechanics and the design of novel materials with applications on emerging quantum technologies. In this context, this Letter explores the potential of molecular magnets to be prototypes of materials for quantum information technology. More precisely, we engineered a material and from its geometric quantum discord we found significant quantum correlations up to 9540 K (even without entanglement); and, in addition, a pure singlet state occupied up to around 80 K (above liquid nitrogen temperature). These results could only be achieved due to the carboxylate group promoting a metal-to-metal huge magnetic interaction. Keywords: Quantum discord, Geometric correlations, Molecular magnetsQuantum entanglement has received a considerable attention as a remarkable resource for quantum information processing [1][2][3]. In spite of that, it is fragile and can easily vanish due to the inevitable interaction of the system with its environment [4]; and due to this condition, it was thought that entanglement could only exist at low temperatures. However, recently, it has been shown that entanglement can also exist at higher temperatures, and can be detected through the measurement of some thermodynamic observables [5][6][7][8][9][10][11][12][13][14][15][16][17].Nevertheless, quantum entanglement does not encompass all quantum correlations in a system and recent studies have greatly expanded the notion of quantum correlations [18][19][20][21][22][23][24][25][26][27][28][29]; and the measure of quantum excess of correlations has been named as quantum discord [19][20][21]. In the last years, it was understood that quantum discord has an important role in many quantum information processing even without entanglement. Notably, this quantity can also detect quantum phase transitions [25,30,31].Despite much effort by the scientific community, there are only a few results on the analytical expression of quantum discord; and only for a certain class of states an exact solution is known [23-27, 32, 33]. This fact stimulated alternative measurements of quantum discord, theoretically and experimentally [22,24,29,[34][35][36]. The recent demonstration that quantum discord can be measured by the thermodynamic properties of solids, such as magnetic susceptibility, internal energy [35][36][37], specific heat [35,36] and even neutron scattering data [22], shows that quantum correlations can be related to significant macroscopic effects allowing the measurement and the control of quantum correlations in solid state systems by means of material engineering. Thus, the design of novel materials becomes an actual challenge to overcome.In this direction, molecular magnets can be an excellent opportunity to achieve this goal as prototypes of materials for quantum information technology. They combine classical properties, found in any macroscopic magnet, with quantum one...

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Witnessing Entanglement and Quantum Correlations in Condensed Matter: A Review

Laurell,

Scheie,

Dagotto

et al. 2024

Adv Quantum Tech

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The detection and certification of entanglement and quantum correlations in materials is of fundamental and far‐reaching importance, and has seen significant recent progress. It impacts both the understanding of the basic science of quantum many‐body phenomena as well as the identification of systems suitable for novel technologies. Frameworks suitable to condensed matter that connect measurements to entanglement and coherence have been developed in the context of quantum information theory. These take the form of entanglement witnesses and quantum correlation measures.The underlying theory of these quantities, their relation to condensed matter experimental techniques, and their application to real materials are comprehensively reviewed. In addition, their usage in, e.g., protocols, the relative advantages and disadvantages of witnesses and measures, and future prospects in, e.g., correlated electrons, entanglement dynamics, and entangled spectroscopic probes, are presented. Consideration is given to the interdisciplinary nature of this emerging research and substantial ongoing progress by providing an accessible and practical treatment from fundamentals to application. Particular emphasis is placed on quantities accessible to collective measurements, including by susceptibility and spectroscopic techniques. This includes the magnetic susceptibility witness, one‐tangle, concurrence and two‐tangle, two‐site quantum discord, and quantum coherence measures such as the quantum Fisher information.

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Entanglement and Bell’s inequality violation above room temperature in metal carboxylates

Cited by 48 publications

References 36 publications

Compostos magnéticos moleculares: o desenvolvimento de novos materiais magnéticos nanoestruturados

Compostos magnéticos moleculares: o desenvolvimento de novos materiais magnéticos nanoestruturados

Carboxylate-based molecular magnet: One path toward achieving stable quantum correlations at room temperature

Witnessing Entanglement and Quantum Correlations in Condensed Matter: A Review

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