Your search keyword '"Mukherjee, Shourya"' showing total 3 results

1. Electroweak Phase Transition in Two Scalar Singlet Model with pNGB Dark Matter

Author

Ghosh, Dilip Kumar, Mukherjee, Koustav, and Mukherjee, Shourya

Subjects

High Energy Physics - Phenomenology

Abstract

We investigate the dynamics of the electroweak phase transition within an extended Standard Model framework that includes one real scalar $(\Phi)$ and one complex scalar $(S)$, both of which are SM gauge singlets. The global $U(1)$ symmetry is softly broken to a $\mathcal{Z}_3$ symmetry by the $S^3$ term in the scalar potential. After this $U(1)$ symmetry breaking, the imaginary component of the complex scalar $(S)$ acts as a pseudo-Nambu-Goldstone boson (pNGB) dark matter candidate, naturally stabilized by $\mathcal{Z}_2$ symmetry of the scenario. Specially, the spontaneous breaking of the global $U(1)$ symmetry to a discrete $\mathcal{Z}_3$ subgroup can introduce effective cubic terms in the scalar potential, which facilitates a strong first-order phase transition. We analyze both single-step and multi-step first-order phase transitions, identifying the parameter space that satisfies the dark matter relic density constraints, complies with all relevant experimental constraints, and exhibits a strong first-order electroweak phase transition. The interplay of these criteria significantly restricts the model parameter space, often leading to an under-abundant relic density. Moreover, we delve into the gravitational wave signatures associated with this framework, offering valuable insights that complement traditional dark matter direct and indirect detection methods., Comment: 51 pages, 10 figures, 7 tables

Published

2024

2. The Influence of Space Traffic on AIM/CIPS PMC Frequencies at 80°N.

Author

Mukherjee, Shourya, Stevens, Michael H., Randall, Cora E., Harvey, V. Lynn, Bailey, Scott M., Carstens, Justin N., and Lumpe, Jerry D.

Subjects

*ATMOSPHERIC water vapor, *NOCTILUCENT clouds, *WATER vapor, *LAUNCH vehicles (Astronautics), *MERIDIONAL winds

Abstract

We explore the effects of lower thermospheric water vapor deposited by launch vehicle plumes on polar mesospheric cloud (PMC) frequencies at 80°N. We use July‐averaged PMC frequencies from 2007 to 2022 from the Cloud Imaging and Particle Size (CIPS) instrument on NASA's Aeronomy of Ice in the Mesosphere (AIM) satellite. Launch sites worldwide are typically located near northern mid‐latitudes. Using the orbital launch record for the same time period, we find that the number of launches correlates with PMC frequencies with a coefficient of r = 0.60, which increases to r = 0.75 when only selecting launches from 2.5 to 21.5 local time (LT), indicating a weak LT dependence on global‐scale transport to 80°N. To support our findings, we use meridional winds from the Michelson Interferometer for Global High‐resolution Imaging experiment on NASA's Ionospheric Connection Explorer satellite and winds from the Horizontal Wind Model climatology to interpret the northward motion of air parcels at 105 km. We find the launch LT window that maximizes the correlation coefficient to be consistent with the expected maximum northward motion from the diurnal variation of mid‐latitude meridional winds. Comparisons with Microwave Limb Sounder satellite observations of upper mesospheric temperature and water vapor reveal a strong dependence of cloud frequency on water vapor (r = 0.86) but not on temperature (r = −0.26), indicating that water vapor is the primary source of PMC variability for the bright PMCs at 80°N. We therefore find that launch vehicle plumes originating primarily from northern mid‐latitudes modulate PMC frequency at 80°N in July. Plain Language Summary: Formation of clouds in the mesosphere in the polar summer depends heavily on atmospheric water vapor. Main engine exhaust plumes from space shuttles and other launch vehicles contain many tons of water vapor which can be transported poleward at an altitude of ∼105 km. Over several days this water vapor descends to ∼80–85 km and aids in the formation of summertime polar mesospheric clouds (PMCs). This work shows how the number of launches per year correlates with the mean interannual PMC frequency averaged over July at 80°N latitude. The correlation maximizes for vehicles launched from 2.5 to 21.5 local time. To provide additional important evidence for the poleward transport of plumes launched at these local times, we use wind data to quantify the maximum northward motion of an exhaust plume over the diurnal cycle near 105 km altitude. We also use satellite temperature and water vapor data at PMC altitudes to show that bright PMCs vary more with the water vapor content than with the air temperature. We conclude that the total water vapor deposited by summertime space traffic worldwide modulates the PMC frequency at 80°N. Key Points: The correlation between orbital rocket launches and polar mesospheric clouds at 80°N in July from 2007 to 2022 is quantifiedMeridional wind, temperature, and water vapor data are used to support causal interpretation of the correlation coefficientsEvidence indicates that water vapor in space traffic exhaust plumes modulates frequencies of polar mesospheric clouds at 80°N [ABSTRACT FROM AUTHOR]

Published

2024

3. A Semi-Analytical Method for Modelling of EC Probes for Detection of Thin Defects in Metals

Author

Mukherjee, Shourya, primary, Sen, Tapabrata, additional, Anoop, C. S., additional, and Sen, Siddhartha, additional

Published

2021