# | Title | Journal | Year | Citations |
---|
1 | Encyclopædia Inflationaris | Physics of the Dark Universe | 2014 | 738 |
2 | The clustering of massive Primordial Black Holes as Dark Matter: Measuring their mass distribution with advanced LIGO | Physics of the Dark Universe | 2017 | 433 |
3 | The characterization of the gamma-ray signal from the central Milky Way: A case for annihilating dark matter | Physics of the Dark Universe | 2016 | 405 |
4 | ΛCDM: Problems, solutions, and the road ahead">BeyondΛCDM: Problems, solutions, and the road ahead | Physics of the Dark Universe | 2016 | 361 |
5 | Primordial black holes from single field models of inflation | Physics of the Dark Universe | 2017 | 345 |
6 | MontePython 3: Boosted MCMC sampler and other features | Physics of the Dark Universe | 2019 | 315 |
7 | Two emission mechanisms in the Fermi Bubbles: A possible signal of annihilating dark matter | Physics of the Dark Universe | 2013 | 262 |
8 | Simplified models for dark matter searches at the LHC | Physics of the Dark Universe | 2015 | 250 |
9 | Exploring the role of axions and other WISPs in the dark universe | Physics of the Dark Universe | 2012 | 242 |
10 | On primordial black holes from an inflection point | Physics of the Dark Universe | 2017 | 242 |
11 | The ORGAN experiment: An axion haloscope above 15 GHz | Physics of the Dark Universe | 2017 | 217 |
12 | Double-Disk Dark Matter | Physics of the Dark Universe | 2013 | 205 |
13 | Gamma ray signals from dark matter: Concepts, status and prospects | Physics of the Dark Universe | 2012 | 203 |
14 | H0 and cosmic shear tensions">Interacting dark energy in the early 2020s: A promising solution to the H0 and cosmic shear tensions | Physics of the Dark Universe | 2020 | 184 |
15 | lenstronomy: Multi-purpose gravitational lens modelling software package | Physics of the Dark Universe | 2018 | 156 |
16 | Semiconductor probes of light dark matter | Physics of the Dark Universe | 2012 | 154 |
17 | Numerical simulations of the dark universe: State of the art and the next decade | Physics of the Dark Universe | 2012 | 137 |
18 | LHC probes the hidden sector | Physics of the Dark Universe | 2013 | 135 |
19 | Seven hints for primordial black hole dark matter | Physics of the Dark Universe | 2018 | 131 |
20 | Searching for galactic axions through magnetized media: The QUAX proposal | Physics of the Dark Universe | 2017 | 127 |
21 | Dark Matter benchmark models for early LHC Run-2 Searches: Report of the ATLAS/CMS Dark Matter Forum | Physics of the Dark Universe | 2020 | 126 |
22 | The role of non-gaussianities in primordial black hole formation | Physics of the Dark Universe | 2019 | 121 |
23 | Cosmic conundra explained by thermal history and primordial black holes | Physics of the Dark Universe | 2021 | 108 |
24 | f(R) theories: Small radii, large masses and large energy emitted in a merger">On neutron stars in f(R) theories: Small radii, large masses and large energy emitted in a merger | Physics of the Dark Universe | 2016 | 104 |
25 | Direct dark matter detection: The next decade | Physics of the Dark Universe | 2012 | 102 |
26 | Neutrino mass limits: Robust information from the power spectrum of galaxy surveys | Physics of the Dark Universe | 2016 | 99 |
27 | Planck and the local Universe: Quantifying the tension | Physics of the Dark Universe | 2013 | 97 |
28 | F(Q) gravity with redshift space distortions">Testing F(Q) gravity with redshift space distortions | Physics of the Dark Universe | 2020 | 95 |
29 | Detecting the gravitational wave background from primordial black hole dark matter | Physics of the Dark Universe | 2017 | 88 |
30 | MadDM v.3.0: A comprehensive tool for dark matter studies | Physics of the Dark Universe | 2019 | 88 |
31 | Hairy black holes by gravitational decoupling | Physics of the Dark Universe | 2021 | 88 |
32 | f(R,T) gravity theory">Gravitational decoupling minimal geometric deformation model in modified f(R,T) gravity theory | Physics of the Dark Universe | 2020 | 86 |
33 | f(R,T) gravity: A minimal geometric deformation gravitational decoupling approach">Charged anisotropic compact star in f(R,T) gravity: A minimal geometric deformation gravitational decoupling approach | Physics of the Dark Universe | 2020 | 83 |
34 | f(T,B)gravity">Thermodynamics and cosmological reconstruction inf(T,B)gravity | Physics of the Dark Universe | 2018 | 80 |
35 | Mimicking dark matter and dark energy in a mimetic model compatible with GW170817 | Physics of the Dark Universe | 2018 | 77 |
36 | The galaxy power spectrum take on spatial curvature and cosmic concordance | Physics of the Dark Universe | 2021 | 76 |
37 | Next decade of sterile neutrino studies | Physics of the Dark Universe | 2012 | 74 |
38 | Construction of charged cylindrical gravastar-like structures | Physics of the Dark Universe | 2020 | 73 |
39 | Ultralight repulsive dark matter and BEC | Physics of the Dark Universe | 2016 | 70 |
40 | f(R,T) gravity">Stability of self-gravitating anisotropic fluids in f(R,T) gravity | Physics of the Dark Universe | 2020 | 64 |
41 | Searching for low mass dark portal at the LHC | Physics of the Dark Universe | 2013 | 63 |
42 | f(R,T,RμνTμν)">New definition of complexity factor in f(R,T,RμνTμν) | Physics of the Dark Universe | 2020 | 62 |
43 | 4D Einstein–Gauss–Bonnet and Einstein–Lovelock gravities">(In)stability of black holes in the 4D Einstein–Gauss–Bonnet and Einstein–Lovelock gravities | Physics of the Dark Universe | 2020 | 60 |
44 | WIMP physics with ensembles of direct-detection experiments | Physics of the Dark Universe | 2014 | 57 |
45 | Signs of dynamical dark energy in current observations | Physics of the Dark Universe | 2019 | 57 |
46 | Radiating black holes in the novel 4D Einstein–Gauss–Bonnet gravity | Physics of the Dark Universe | 2020 | 57 |
47 | S8 tension with the Redshift Space Distortion data set">Quantifying the S8 tension with the Redshift Space Distortion data set | Physics of the Dark Universe | 2021 | 57 |
48 | MadDM v.1.0: Computation of dark matter relic abundance using MadGraph 5 | Physics of the Dark Universe | 2014 | 56 |
49 | Tsallis holographic dark energy in the brane cosmology | Physics of the Dark Universe | 2019 | 56 |
50 | f(R,T) gravity under class I spacetime">Decoupling gravitational sources in f(R,T) gravity under class I spacetime | Physics of the Dark Universe | 2021 | 55 |