Abstract
We study decoherence effects in neutrino flavour oscillations in curved spacetime with particular emphasis on the lensing in a Schwarzschild geometry. Assuming Gaussian wave packets for neutrinos, we argue that the decoherence length derived from the exponential suppression of the flavour transition amplitude depends on the proper time of the geodesic connecting the events of the production and detection in general gravitational setting. In the weak gravity limit, the proper time between two events of given proper distance is smaller than that in the flat spacetime. Therefore, in presence of a Schwarzschild object, the neutrino wave packets have to travel relatively more physical distance in space to lapse the same amount of proper time before they decoher. For non-radial propagation applicable to the lensing phenomena, we show that the decoherence, in general, is sensitive to the absolute values of neutrino masses as well as the classical trajectories taken by neutrinos between the source and detector along with the spatial widths of neutrino wave packets. At distances beyond the decoherence length, the probability of neutrino flavour transition due to lensing attains a value which depends only on the leptonic mixing parameters. Hence, the observability of neutrino lensing significantly depends on these parameters and in-turn the lensing can provide useful information about them.
Highlights
Neutrino oscillations, in curved spacetime has gained attention in recent times [1,2], for the reason that such analysis is sensitive to the background geometry and the gravity theory at work [3,4,5,6,7,8,9,10,11] but they reveal some salient features of the neutrino sector which are not present in flat spacetime [12,13]
Gravitational lensing where different trajectories of neutrinos around a massive astrophysical body get focused on a point of detection and its effects on flavor oscillations are studied in the context of Schwarzschild geometry in [2,16,17,18,19,20]
It can be shown that in order to traverse a particular amount of proper time, one has to travel more in terms of physical distance in the Schwarzschild spacetime compared to the flat space
Summary
In curved spacetime has gained attention in recent times [1,2], for the reason that such analysis is sensitive to the background geometry and the gravity theory at work [3,4,5,6,7,8,9,10,11] but they reveal some salient features of the neutrino sector which are not present in flat spacetime [12,13]. Gravitational lensing where different trajectories of neutrinos around a massive astrophysical body get focused on a point of detection and its effects on flavor oscillations are studied in the context of Schwarzschild geometry in [2,16,17,18,19,20]. Relatively less attention for neutrino propagation in the curved geometry These effects have been investigated in [29,30] for neutrinos traveling radially inward or outward in the background of the Schwarzschild metric.
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