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Inversión del Flujo de Calor por Coherencia en un Sistema Cuántico Multipartito

Keyi Huang1, Qi Zhang2, Xiangjing Liu3

  • 1Southern University of Science and Technology, Department of Physics, State Key Laboratory of Quantum Functional Materials, and Guangdong Basic Research Center of Excellence for Quantum Science, Shenzhen 518055, China.

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|February 22, 2026
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Resumen
Este resumen es generado por máquina.

La coherencia cuántica en sistemas de espín multipartitos puede revertir el flujo de calor, desafiando la termodinámica clásica. Las propiedades cuánticas locales permiten un control preciso sobre la dirección y la magnitud de la transferencia de energía.

Palabras clave:
termodinámica cuánticaflujo de calor cuánticocoherencia cuánticasistemas de espín multipartitostransferencia de energíamecánica cuántica

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Área de la Ciencia:

  • Termodinámica Cuántica
  • Ciencia de la Información Cuántica
  • Física de la Materia Condensada

Sus antecedentes:

  • La segunda ley de la termodinámica dicta tradicionalmente el flujo de calor espontáneo de caliente a frío.
  • Estudios recientes muestran que las correlaciones cuánticas pueden revertir este flujo, desafiando las expectativas clásicas.
  • Se exploran los estados cuánticos internos, no solo las correlaciones ambientales, para el control del flujo de calor.

Objetivo del estudio:

  • Demostrar experimentalmente la reversión del flujo de calor utilizando coherencia cuántica interna.
  • Investigar el papel de la coherencia en sistemas de espín multipartitos para la transferencia de energía.
  • Establecer el control sobre la dirección y la magnitud del flujo de calor a través de propiedades cuánticas locales.

Principales métodos:

  • Utilizando un sistema de espín multipartito con coherencia cuántica interna.
  • Empleando el modelo de colisión con interacción en cascada para la simulación.
  • Analizando el impacto de la fuerza y la fase de la coherencia en la transferencia de energía.

Principales resultados:

  • Se demostró que la coherencia cuántica interna revierte el flujo de calor sin correlaciones ambientales.
  • Se encontró que la fuerza y la fase de la coherencia dictan la dirección y la magnitud de la transferencia de energía.
  • Se logró un control preciso del flujo de calor utilizando únicamente propiedades cuánticas locales.

Conclusiones:

  • La coherencia cuántica interna es un mecanismo viable para revertir el flujo de calor.
  • Las propiedades cuánticas ofrecen métodos novedosos para manipular procesos termodinámicos.
  • Esta investigación abre vías para controlar la transferencia de energía a nivel cuántico.