Descripción del proyecto
Un novedoso diseño experimental consigue que los gases cuánticos sean balísticos
Normalmente, la conducción o el transporte balístico hace referencia al movimiento de portadores de carga, como electrones o huecos, a lo largo de grandes distancias sin que las interacciones de dispersión lo impidan, algo parecido al movimiento de una bala a mucha velocidad. Aunque los científicos han teorizado que no solo debería aplicarse a las cargas eléctricas, hace pocos años se observaron por primera vez átomos neutros en régimen ultrabalístico en un tipo especial de gas cuántico a temperaturas ultrabajas. El proyecto QCNGas, financiado con fondos europeos, está desarrollando una plataforma experimental innovadora que permitirá investigar la conductancia cuántica de los gases en función de una temperatura de hasta 4 K. Los estudios contribuirán a la búsqueda de nuevos materiales con transporte balístico cerca de la temperatura ambiente.
Objetivo
We propose to design a new insert with a sample-holder and investigate quantum aspects of flow (gas) conductance as a function of temperature (T) down to 4K by exploiting de Broglie wavelength for neutral helium (He) atoms through an atomically-flat rectangular graphene nanochannel in a molecular flow regime. By confining the vertical length of the transport channel and tuning the associated de Broglie wavelength (with T), the realization of the quantum limited conductance for He gas flow, similar to the observed quantum signatures of conductance for electrons, seems to be truly within the experimental reach. The behaviour of the wall switches over to more rigid (lowering atomic vibrations) from flexible one at room T which not only enhances the specular reflection but also the phase coherence of the associated de Broglie wavelength. We will investigate the transport properties using layered materials from transition metal dichalcogenides (TMDs) family to induce ballistic transport from the diffusive transport regime at room T via Laser-irradiation and chemical roots which will heal the defects in TMDs at atomic scale. Our investigations will help in search of more materials to have the ballistic transport around room T. Our focus will not only be on the enhanced flow due to quantum effects but also the understanding from fundamental physics point of view as well as exploring in broader perspective. The strategy of the project is to design a setup for low-T, making state-of-the-art devices, investigate the quantum signatures of conductance of nanoscale channels and address various important issues. Completion of the multidisciplinary project will open up a new era where various novel intriguing physics need to be explored further, understanding of quantum gas transport will boost many biomedical and industrial applications, next generation devices using gas sensors and properties of thermal transport exploited to extract heat will be tuned with enhanced performance.
Ámbito científico
Programa(s)
Régimen de financiación
MSCA-IF - Marie Skłodowska-Curie Individual Fellowships (IF)Coordinador
M13 9PL Manchester
Reino Unido