Patterning Polyelectrolyte Complexes with Alternating Monomer Sequence Distributions

Herzog‐Arbeitman, Abraham; Ting, Jeffrey; Meng, Siqi; Wu, Hao; Tirrell, Matthew

doi:10.26434/chemrxiv.11320439.v1

Cited by 8 publications

(9 citation statements)

References 57 publications

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“…In this case, convergence in the velocity distributions was reached for stars with iron abundance [Fe/H] −3. This result motivated a first study using the RAVE-TGAS dataset to recover the velocity distribution of the local relaxed DM component (Herzog-Arbeitman et al 2018b).…”

Section: Introductionmentioning

confidence: 75%

Under the FIRElight: Stellar Tracers of the Local Dark Matter Velocity Distribution in the Milky Way

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Lisanti

Garrison-Kimmel

et al. 2019

ApJ

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The Gaia era opens new possibilities for discovering the remnants of disrupted satellite galaxies in the Solar neighborhood. If the population of local accreted stars is correlated with the dark matter sourced by the same mergers, one can then map the dark matter distribution directly. Using two cosmological zoom-in hydrodynamic simulations of Milky Way-mass galaxies from the Latte suite of Fire-2 simulations, we find a strong correlation between the velocity distribution of stars and dark matter at the solar circle that were accreted from luminous satellites. This correspondence holds for dark matter that is either relaxed or in kinematic substructure called debris flow, and is consistent between two simulated hosts with different merger histories. The correspondence is more problematic for streams because of possible spatial offsets between the dark matter and stars. We demonstrate how to reconstruct the dark matter velocity distribution from the observed properties of the accreted stellar population by properly accounting for the ratio of stars to dark matter contributed by individual mergers. After demonstrating this method using the Fire-2 simulations, we apply it to the Milky Way and use it to recover the dark matter velocity distribution associated with the recently discovered stellar debris field in the Solar neighborhood. Based on results from Gaia, we estimate that 42 +26 −22 % of the local dark matter that is accreted from luminous mergers is in debris flow.

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Section: Introductionmentioning

confidence: 75%

Under the FIRElight: Stellar Tracers of the Local Dark Matter Velocity Distribution in the Milky Way

Necib

Lisanti

Garrison-Kimmel

et al. 2019

ApJ

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“…This value may increase if the standard halo model is extended, e.g. by the inclusion of tidal DM streams from galactic mergers [10,11]. However in the case of sub-GeV DM there is another possibility to generate faster DM particles in the solar system, which has the advantage of being widely halo model independent.…”

Section: Introductionmentioning

confidence: 99%

The Sun as a sub-GeV dark matter accelerator

2018

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Sub-GeV halo dark matter that enters the Sun can potentially scatter off hot solar nuclei and be ejected much faster than its incoming velocity. We derive an expression for the rate and velocity distribution of these reflected particles, taking into account the Sun's temperature and opacity. We further demonstrate that future direct-detection experiments could use these energetic reflected particles to probe light dark matter in parameter space that cannot be accessed via ordinary halo dark matter.

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“…[35] used Eddington's method to derive the local VDF from various dynamical constraints on the gross properties of the Galaxy rather than the full RC data as done here. There has also been a recent study using the local kinematics of stars to estimate the local DM VDF [66]; however, similar to [18], the implications of the inferred VDF on DM direct detection, as compared to using the SHM, was simplistically taken to be given by only the ratio of the corresponding velocity integrals (described in detail later in this work).…”

Section: Discussionmentioning

confidence: 99%

Observationally inferred dark matter phase-space distribution and direct detection experiments

et al. 2019

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We present a detailed analysis of the effect of an observationally determined dark matter (DM) velocity distribution function (VDF) of the Milky Way (MW) on DM direct detection rates. We go beyond local kinematic tracers and use rotation curve data up to 200 kpc to construct a MW mass model and self-consistently determine the local phase-space distribution of DM. This approach mitigates any incomplete understanding of local dark matter-visible matter degeneracies that can affect the determination of the VDF. Comparing with the oft used Standard Halo Model (SHM), which assumes an isothermal VDF, we look at how the tail of the empirically determined VDF alters our interpretation of the present direct detection WIMP DM cross section exclusion limits. While previous studies have suggested a very large difference (of more than an order of magnitude) in the bounds at low DM masses, we show that accounting for the detector response at low threshold energies, the difference is still significant although less extreme. The change in the number of signal events, when using the empirically determined DM VDF in contrast to the SHM VDF, is most prominent for low DM masses for which the shape of the recoil energy spectrum depends sensitively on the detector threshold energy as well as detector response near the threshold. We demonstrate that these trends carry over to the respective DM exclusion limits, modulo detailed understanding of the experimental backgrounds. With the unprecedented precision of astrometric data in the GAIA era, use of observationally determined DM phase-space will become a critical and necessary ingredient for DM searches. We provide an accurate fit to the current best observationally determined DM VDF (and self-consistent local DM density) for use in analyzing current DM direct detection data by the experimental community.

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Patterning Polyelectrolyte Complexes with Alternating Monomer Sequence Distributions

Cited by 8 publications

References 57 publications

Under the FIRElight: Stellar Tracers of the Local Dark Matter Velocity Distribution in the Milky Way

Under the FIRElight: Stellar Tracers of the Local Dark Matter Velocity Distribution in the Milky Way

The Sun as a sub-GeV dark matter accelerator

Observationally inferred dark matter phase-space distribution and direct detection experiments

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