Fact-checked by Grok 2 weeks ago

Modified Newtonian dynamics

Modified Newtonian dynamics (MOND) is a theoretical framework that alters the Newtonian laws of or in regimes of very low , serving as an alternative to the paradigm for interpreting anomalous gravitational phenomena in astronomical systems. Introduced by Israeli physicist in 1983, MOND proposes that when the Newtonian g_N falls below a fundamental threshold a_0 \approx 1.2 \times 10^{-10} m s^{-2}, the true g follows a nonlinear relation g = \mu(g / a_0) g_N, where the interpolation function \mu(x) \approx x for x \ll 1, yielding g \approx \sqrt{g_N a_0} in the deep-MOND limit. This modification was motivated primarily by the observed flat curves of spiral , where orbital velocities remain roughly constant at large radii rather than declining as predicted by Newtonian gravity based on visible mass alone, implying an apparent mass discrepancy that MOND attributes to a breakdown of standard dynamics rather than unseen matter. Over the decades, MOND has demonstrated phenomenological success across diverse scales, accurately predicting not only galaxy curves but also the baryonic Tully-Fisher relation—which correlates a 's total baryonic mass with its asymptotic speed as v^4 \propto M_b—as well as velocity dispersions in low-mass systems like dwarf spheroidal , globular clusters, and even wide binary stars in the solar neighborhood. Despite these strengths, particularly on galactic and sub-galactic scales, MOND faces challenges in reproducing observations on larger structures, such as the dynamics of galaxy clusters, where the predicted accelerations often fall short unless supplemented by non-baryonic particles like massive neutrinos or phantom dark matter; it also struggles with early-universe cosmology, including the and , necessitating relativistic generalizations like Bekenstein's tensor-vector-scalar (TeVeS) theory to incorporate . Ongoing empirical tests, including those from gravitational lensing and wide binaries, continue to probe MOND's viability, while theoretical efforts explore possible microscopic origins tied to quantum vacuum fluctuations or emergent gravity.

Introduction and Motivation

Historical Development

The discrepancies in galaxy dynamics observed during the 1970s provided the initial motivation for alternatives to standard Newtonian gravity. Astronomers Vera Rubin and Kent Ford, through spectroscopic observations of spiral galaxies such as Andromeda (M31), found that orbital velocities of stars and gas remained roughly constant at large radii rather than declining as predicted by Keplerian motion, suggesting either unseen mass or a modification to gravitational laws. These findings, extended to a broader sample of 21 galaxies in subsequent work, highlighted a systematic "missing mass" issue in galactic outskirts and spurred theoretical responses. In response to these observations, Israeli physicist Mordehai Milgrom proposed Modified Newtonian Dynamics (MOND) in 1983 as a paradigm that alters Newtonian laws at low accelerations to account for the observed phenomena without invoking hidden mass. Milgrom's seminal work consisted of three papers published in the Astrophysical Journal, where he outlined the core idea that dynamics deviate from Newtonian predictions below a characteristic acceleration scale, offering a simple empirical fit to galaxy data. This proposal, conceived in 1981 and first presented in 1982, positioned MOND as a direct alternative to dark matter hypotheses that had been gaining traction since Fritz Zwicky's earlier suggestions in the 1930s. The initial reception of MOND in the astronomical community during the mid-1980s was largely skeptical and negative, viewed by many as an adjustment lacking broader theoretical foundations. Despite this, Milgrom and collaborator advanced the framework by developing its first non-relativistic field-theoretic formulation, known as the aquadratic (AQUAL) theory, in 1984, which provided a nonlinear equation to compute gravitational fields consistently with MOND principles. This formulation enabled quantitative predictions for isolated systems and marked an early step toward rigorizing the paradigm. Throughout the 1990s, MOND's development continued amid intense debates with proponents of the emerging (CDM) model, which integrated and to explain not only galaxy dynamics but also large-scale and cosmic microwave background fluctuations. Milgrom and others applied MOND to diverse systems like galaxy clusters and dwarf galaxies, refining its interpolating functions through numerical simulations, but the paradigm struggled against CDM's unified explanatory power and support from a growing research community. These debates, often centered on figures like Philip Peebles and George Efstathiou advocating for , underscored MOND's marginalization as an outlier until renewed interest in the early 2000s prompted further theoretical extensions.

The Missing Mass Problem

In the , early applications of the to galaxy clusters revealed significant discrepancies between the visible mass of galaxies and the mass required to explain their observed velocity dispersions. Fritz Zwicky's analysis of the Coma Cluster, for instance, indicated that the dynamical mass exceeded the luminous mass by a factor of approximately 400, suggesting the presence of substantial unseen mass to maintain gravitational binding. This "missing mass" problem became more pronounced in the with detailed spectroscopic observations of individual galaxies, highlighting inconsistencies in galactic dynamics under standard Newtonian gravity. A key manifestation of the missing mass problem appears in the rotation curves of spiral galaxies, where orbital speeds of stars and gas are expected to decline inversely with the of (Keplerian falloff) beyond the luminous disk, as the enclosed should stabilize. Instead, observations show nearly flat rotation curves, with velocities remaining roughly constant at large , implying that the enclosed continues to increase linearly with from the center. This , first systematically documented in high-luminosity spirals, indicates a discrepancy that grows outward, often by factors of 3 to 10 in the galaxy outskirts, where luminous contributes only 10-70% of the dynamical . The Tully-Fisher relation further underscores these discrepancies, empirically correlating the intrinsic L of spiral galaxies with the fourth power of their maximum rotation speed, L \propto v^4. This steep scaling suggests that fainter galaxies rotate more slowly than expected if their dynamics were governed solely by visible mass, requiring additional unseen mass to reconcile the relation across diverse galaxy types. In galaxy clusters, the similarly demands unseen mass to balance the high-velocity motions, with dynamical estimates often exceeding luminous masses by orders of magnitude. Specific observations of the (M31) exemplify the issue: its rotation curve rises to about 225 km/s near the nucleus and remains flat out to several disk scale lengths, implying the presence of unseen mass in the outskirts. Such findings across spirals and clusters collectively point to a pervasive shortfall in accounted-for mass, challenging Newtonian predictions and motivating deeper investigation into gravitational dynamics.

Core Principles of MOND

Milgrom's Law

Milgrom's law forms the foundational postulate of Modified Newtonian Dynamics (MOND), proposing a nonlinear modification to Newton's second law in regimes of weak acceleration to address discrepancies in galactic dynamics without invoking unseen mass. In this framework, the true gravitational acceleration \mathbf{g} experienced by a test particle relates to the Newtonian acceleration \mathbf{g}_N through an interpolating function \mu(|\mathbf{g}|/a_0), such that \mathbf{g}_N = \mu(|\mathbf{g}|/a_0) \mathbf{g}, where a_0 is a fundamental acceleration scale. This modification ensures that Newtonian gravity is recovered in strong-field limits while altering the dynamics in weak fields. In the deep-MOND regime, where the acceleration a = |\mathbf{g}| \ll a_0, the function \mu(x) \approx x for x \ll 1, leading to the core equation a \approx \sqrt{a_N a_0}, with a_N = |\mathbf{g}_N|. Here, the actual acceleration scales as the square root of the Newtonian prediction times a_0, effectively enhancing the gravitational force in low-acceleration environments. The acceleration scale a_0 is empirically determined to be approximately $1.2 \times 10^{-10} m/s², marking the transition between Newtonian and MONDian behaviors. This value emerges from fits to observed galactic rotation curves and is intriguingly close to the cosmological combination c H_0 / (2\pi), where c is the speed of light and H_0 is the Hubble constant, suggesting a possible deeper connection to cosmic scales. Physically, Milgrom's interprets the strengthening of in weak fields as a natural resolution to the missing mass problem in galaxies, producing flat rotation curves and other phenomena typically attributed to without requiring additional particles. The implies that at accelerations below a_0, the effective gravitational attraction increases, mimicking the effects of distributed unseen mass on visible baryons alone. The derivation of Milgrom's law stems from empirical analysis of galactic rotation curves, where observed orbital velocities in the outskirts of galaxies exceed Newtonian predictions based on visible matter. By assuming a universal acceleration scale and fitting the modified dynamics to these curves across multiple systems, Milgrom identified the square-root relation as the simple form that consistently reproduces the data, establishing the MOND paradigm as an alternative to dark matter hypotheses. This approach prioritizes the universality of the modification over system-specific adjustments.

Interpolating Function

In Modified Newtonian Dynamics (MOND), the interpolating provides a mechanism to bridge the Newtonian regime at high and the deep-MOND regime at low , ensuring a smooth transition without abrupt changes. The general form relates the Newtonian acceleration \mathbf{g}_N to the true \mathbf{g} via \mathbf{g}_N = \mu(|\mathbf{g}| / a_0) \mathbf{g}, where a_0 is a fundamental (approximately $1.2 \times 10^{-10} m s^{-2}), and \mu is a dimensionless that interpolates between the two limits. The function \mu(x), with x = |\mathbf{g}| / a_0, must satisfy specific asymptotic behaviors: \mu(x) \to [1](/page/1) as x \gg [1](/page/1) to recover standard Newtonian dynamics in strong-field environments (|\mathbf{g}| \approx |\mathbf{g}_N|), and \mu(x) \to x as x \ll [1](/page/1) to reproduce the deep-MOND limit. In this limit, \mu(x) \approx x implies |\mathbf{g}_N| \approx x |\mathbf{g}| = (|\mathbf{g}|^2 / a_0), so |\mathbf{g}| \approx \sqrt{a_0 |\mathbf{g}_N|}, aligning with Milgrom's law. Common choices for \mu(x) include the simple form \mu(x) = \frac{x}{1 + x}, which offers an analytically straightforward transition, and the "standard" interpolator \mu(x) = \frac{x}{\sqrt{1 + x^2}}, which provides better second-order accuracy in the Newtonian limit by ensuring smoother derivatives. These forms were selected to balance computational simplicity with physical fidelity in applications to galactic . The interpolating function is derived from the requirement of consistency between the Newtonian high-acceleration limit and the MOND low-acceleration regime, as originally motivated by Milgrom to address discrepancies in galactic rotation curves without invoking unseen . Key properties include positivity (\mu(x) > 0 for all x > 0) to preserve the attractive nature of , and strict monotonicity (\frac{d\mu}{dx} > 0) to prevent unphysical instabilities or oscillations in the dynamical equations. These constraints ensure that the modification remains well-behaved across all acceleration scales.

Key Features and Effects

External Field Effect

The external field effect (EFE) in Modified Newtonian Dynamics (MOND) arises from the nonlinearity of the theory, whereby the internal gravitational dynamics of a subsystem are influenced by the ambient external gravitational field from larger structures. Unlike Newtonian gravity, where a uniform external field would simply add a constant acceleration without altering relative motions, the MOND interpolating function depends on the magnitude of the total acceleration, causing the external field to modulate local MOND corrections even when it is steady and uniform. Mathematically, this is captured in the MOND μ(|g| / a_0) g = g_N, where g is the total physical acceleration (g = g_internal + g_external), g_N is the Newtonian acceleration, μ is the interpolating function, and a_0 is the characteristic acceleration scale (~10^{-10} m s^{-2}). When |g_external| >> |g_internal|, the argument of μ approaches |g_external| / a_0 > 1, where μ ≈ 1, suppressing the MOND enhancement and forcing internal dynamics toward the Newtonian regime. A key implication is the suppression of MOND effects in subsystems embedded in strong external fields, such as dwarf satellite galaxies orbiting within the Milky Way's gravitational field, where g_external ~ 1-2 × 10^{-10} m s^{-2} dominates over internal accelerations in low-mass systems. This leads to predicted deviations from isolated MOND behavior, including reduced asymptotic velocities in rotation curves compared to what would be expected without the EFE. Observationally, the EFE manifests as directional asymmetries in the dynamics of affected systems, with stronger MOND-like behaviors aligned against the direction of the external field and weaker effects along it, providing a testable signature distinct from models. For instance, this has been invoked to explain variations in velocity dispersions across dwarf galaxies in the Local Group.

Transition to Newtonian Regime

In Modified Newtonian Dynamics (MOND), the transition to the Newtonian regime occurs when the internal gravitational accelerations surpass the characteristic scale a_0 \approx 1.2 \times 10^{-10} m s^{-2}, the below which MOND deviates from . In this high-acceleration limit, the interpolating function \mu(x), where x = g / a_0 and g is the physical acceleration, asymptotically approaches unity (\mu(x) \to 1 as x \gg 1), such that the MOND acceleration g \approx g_N, with g_N denoting the Newtonian prediction. This behavior ensures that MOND functions as an effective , valid primarily in the low-acceleration relevant to galactic scales, while seamlessly recovering Newtonian gravity in high-acceleration environments to maintain consistency with well-established physics. The theoretical design of MOND, as originally proposed, mandates this limit to avoid conflicts with precision tests in regimes where standard dynamics have been verified, positioning MOND as a low-energy modification rather than a wholesale replacement. Within galaxies, the manifests over radial scales of roughly 10–100 kpc, corresponding to the radii where g_N \sim a_0 for typical baryonic distributions and speeds around 200 km s^{-1}; however, in denser systems like globular clusters or galactic bulges, the shift to Newtonian behavior is more abrupt due to steeper acceleration profiles. Representative examples highlight the negligible impact of MOND in such regimes: planetary orbits experience centripetal accelerations on the order of 0.006 m s^{-2}, orders of magnitude above a_0, yielding deviations from Newtonian predictions below $10^{-6}. Likewise, binary pulsar systems, with orbital accelerations typically on the order of 10^2 m s^{-2}, show MOND corrections that are insignificant compared to observed post-Keplerian parameters.

Theoretical Formulations

AQUAL Formulation

The AQuadratic Lagrangian of MOND (AQUAL) represents the foundational Lagrangian-based framework for Modified Newtonian Dynamics, developed by Jacob Bekenstein and Mordehai Milgrom in 1984 to provide a consistent field-theoretic description of gravitational phenomena in the deep-MOND regime. This formulation modifies the standard Newtonian action by introducing a nonlinear dependence on the gravitational field gradient, enabling the theory to reproduce Milgrom's law as its asymptotic limit for weak accelerations while recovering Newtonian gravity at high accelerations through an appropriate choice of interpolating function. The core of AQUAL lies in its action principle, where the gravitational is constructed to yield the modified field equations upon variation. Specifically, the is given by L = \int \left[ \frac{1}{2} (\nabla \phi)^2 \mu\left( \frac{|\nabla \phi|}{a_0} \right) - \rho \phi \right] dV, with \phi denoting the , \rho the mass density, a_0 the critical scale, and \mu(x) the interpolating function satisfying \mu(x) \to 1 for x \gg 1 and \mu(x) \to x for x \ll 1. Varying this with respect to \phi produces the nonlinear Poisson equation \nabla \cdot \left[ \mu\left( \frac{|\nabla \phi|}{a_0} \right) \nabla \phi \right] = 4\pi G \rho, which governs the potential in the presence of matter and encapsulates the MONDian modification to standard gravity. This equation ensures that the acceleration \mathbf{g} = -\nabla \phi follows the MOND prescription in spherical symmetry, where |\mathbf{g}| \mu(|\mathbf{g}|/a_0) = g_N and g_N is the Newtonian acceleration. One key advantage of AQUAL is its derivation of MOND dynamics directly from an action principle, which guarantees the conservation of momentum and energy in isolated systems, resolving ambiguities in the original phenomenological MOND proposal. Additionally, as a field theory, AQUAL naturally accommodates multi-body interactions by solving the nonlinear equation for the collective potential, facilitating applications to complex systems like galaxies without ad hoc adjustments. Despite these strengths, remains a non-relativistic theory, limiting its applicability to scenarios involving high velocities or strong where special or is required. Furthermore, the nonlinear structure can lead to acausal propagation in certain configurations, posing challenges for consistent extensions to relativistic regimes.

QUMOND Formulation

The quasi-linear formulation of Modified Newtonian Dynamics (QUMOND) was proposed by in 2010 as a reformulation of MOND that expresses the theory in terms of a modified equation for the physical . Unlike the original nonlinear approaches, QUMOND linearizes the relationship between the and the source density, making it computationally more tractable for complex systems. In QUMOND, the MOND gravitational potential \phi obeys the equation \nabla^2 \phi = \nabla \cdot \left[ \nu\left( \frac{|\nabla \Phi_N|}{a_0} \right) \nabla \Phi_N \right], where \Phi_N is the satisfying \nabla^2 \Phi_N = 4\pi [G](/page/G) \rho, \rho is the mass density, a_0 is the MOND acceleration scale, and \nu(y) is an interpolating function with asymptotic behaviors \nu(y) \to 1 for y \gg 1 (Newtonian regime) and \nu(y) \to 1/\sqrt{y} for y \ll 1 (deep-MOND regime). The function \nu(y) is chosen to be consistent with the standard MOND interpolating function \mu(x) via the relation \nu(y) = 1 / \mu(x) where x satisfies y = x \mu(x), ensuring the theory reproduces Milgrom's law in the appropriate limits. This formulation offers several advantages, including its linearity with respect to \rho, which simplifies the implementation of N-body simulations compared to nonlinear theories. Additionally, QUMOND inherently incorporates the external field effect, whereby an ambient external acceleration influences the internal MONDian dynamics of a subsystem, without requiring modifications. QUMOND is mathematically equivalent to the AQUAL formulation in spherically symmetric systems but diverges in general geometries, potentially leading to distinct predictions for non-symmetric mass distributions.

Relativistic and Extended Theories

Need for Relativistic MOND

While the non-relativistic formulations of Modified Newtonian Dynamics (MOND), such as and QUMOND, successfully reproduce galactic rotation curves and other low-acceleration phenomena without invoking , they are inherently limited in addressing relativistic effects. Specifically, these theories fail to provide predictions for gravitational lensing, where light propagation is deflected by massive bodies, as well as cosmological phenomena like the and large-scale , which require a framework consistent with special and at high velocities and curvatures. Additionally, non-relativistic MOND cannot handle scenarios involving strong gravitational fields or high accelerations, such as those near black holes or in the early , where (GR) has been extensively validated. The motivation for developing relativistic extensions of MOND emerged in the early , driven by the need to reconcile MOND's successes on galactic scales with GR's precision in the solar system and the requirement for a consistent description of deflection and cosmic . Pioneering efforts, such as those exploring multi-metric formulations, aimed to modify at large scales while preserving GR's behavior in high-acceleration regimes, thereby altering predictions for extragalactic structures without contradicting local tests. These initial attempts were spurred by observational tensions, including discrepancies in lensing maps and the need for a Lorentz-invariant theory to describe phenomena across cosmic distances. Any viable relativistic MOND must satisfy several key requirements to be physically consistent: it should recover in the high-acceleration limit (where accelerations exceed the MOND a_0 \approx 1.2 \times 10^{-10} m s^{-2}), reproduce MOND's non-relativistic in weak fields, and maintain Lorentz invariance to ensure compatibility with . This reduction to in the Newtonian regime serves as a crucial boundary condition, ensuring the theory passes solar-system tests like the perihelion of Mercury and the . Furthermore, the theory must incorporate mechanisms for scalar or vector fields to mediate the MONDian effects while preserving the causal structure of . Despite these goals, constructing such theories has presented significant challenges, including the risk of superluminal propagation in additional , which could violate , and instabilities like ghosts or tachyons that destabilize solutions. Early formulations often encountered these issues, with scalar fields propagating in certain regimes or leading to runaway modes that undermine the theory's viability. Addressing these problems requires careful tuning of and field content to avoid preferred frames and ensure stable, ghost-free dynamics across all scales.

TeVeS and Other Extensions

(TeVeS), proposed by in , is a relativistic generalization of MOND that incorporates a (the metric g_{\mu\nu}), a \phi, and a timelike field A_\mu to mediate gravitational interactions. The theory is formulated through an action principle, where the scalar field \phi influences the physical metric experienced by matter via disformal transformations, and the vector field A_\mu (normalized to unit timelike length) breaks Lorentz invariance to define a preferred frame. The action includes nonlinear functions \mu (related to the scalar) and \nu (related to the vector) that interpolate between MONDian behavior in the weak-field limit and (GR) in strong fields, ensuring conservation laws are respected due to the covariant formulation. In the nonrelativistic limit, TeVeS recovers the standard MOND acceleration law, with the drawing inspiration from the QUMOND formulation to produce the required modifications. In the opposite regime of weak gravitational fields (high accelerations), it approaches , correctly reproducing solar system tests and other local constraints. A key advantage is its prediction of enhanced gravitational lensing compared to purely scalar MOND theories; the vector and scalar contributions together can match observed lensing in systems like galaxy clusters without invoking , as demonstrated in analytic models of deflection angles and lens equations. TeVeS has undergone testing against various observations, including gravitational lensing data from arcs, where it provides fits comparable to with . Early analyses of timing suggested compatibility with constraints on rates and periastron advances, but a 2021 study using 16 years of data from the double system (PSR J0737−3039) rules out TeVeS due to inconsistencies with the measured post-Keplerian parameters. However, the theory encounters challenges, such as violations of classical conditions (e.g., the null energy condition) in certain regimes, which can lead to instabilities like superluminal propagation or ghost modes, though these are mitigated in ghost-free variants. Beyond TeVeS, other relativistic extensions of MOND include nonlocal formulations, which modify the metric using integrodifferential operators to achieve MONDian effects without additional fields, ensuring and sufficient lensing while avoiding Ostrogradsky instabilities. For instance, nonlocal MOND models employ a free function f(Z) where Z is the nonlocal scalar built from the Ricci scalar, reproducing flat rotation curves and predictions. Bimetric extensions, incorporating two metrics to blend and MOND behaviors, have been explored to address issues, though they remain less developed. More recent developments include a non-linear extension of non-metricity scalar for MOND (2020), which modifies the symmetric teleparallel formulation to recover MOND effects relativistically, and connections between relativistic MOND theories (like TeVeS) and mimetic (2025), which introduce a mimetic to enforce the aether-like structure while resolving some cosmological tensions; these are still under active refinement.

Observational Evidence

Galaxy Rotation Curves

In Modified Newtonian Dynamics (MOND), the observed flat rotation curves of spiral galaxies arise naturally from a modification to Newton's law at low accelerations, without invoking dark matter. The theory posits that when the Newtonian acceleration g_N = GM/r^2 falls below a characteristic scale a_0 \approx 1.2 \times 10^{-10} m/s², the true acceleration g satisfies g \approx \sqrt{g_N a_0}. For a circular orbit, the centripetal acceleration equals g, so v^2 / r = \sqrt{(GM/r^2) a_0}, which simplifies to a constant orbital speed v = (G M a_0)^{1/4} in the deep-MOND regime, independent of radius. This prediction yields the baryonic Tully-Fisher relation, v^4 \propto M, where M is the total baryonic mass of the galaxy, linking asymptotic rotation speeds directly to luminous matter. Empirical tests confirm that MOND quantitatively reproduces the rotation curves of over 150 spiral galaxies using only their observed baryonic mass distributions (stars and gas) and a single universal parameter a_0, with no free adjustments per galaxy beyond mass-to-light ratios constrained by stellar population models. These fits capture both the inner Keplerian rise and the outer flat portions, often achieving reduced chi-squared values near unity, indicating excellent agreement without dark matter halos. For instance, in the Milky Way, MOND models based on axisymmetric baryonic distributions provided good fits to Gaia DR2 and radio data out to ~25 kpc, with an asymptotic speed of ~220 km/s derived solely from the galaxy's stellar and gaseous content. However, more recent Gaia DR3 analyses (as of 2024) indicate a declining rotation curve beyond ~20 kpc, presenting a challenge to MOND's predicted flat asymptote. Similarly, for M31 (Andromeda), MOND fits the extended HI rotation curve to ~35 kpc using its bulge, disk, and gas components, yielding a flat velocity of ~225 km/s consistent with baryonic mass estimates from infrared photometry, though recent data suggest a decline to ~170 km/s beyond ~25 kpc. Compared to Navarro-Frenk-White (NFW) dark matter profiles, which require halo parameters tuned to match data and often predict declining velocities in outer regions beyond ~10 scale radii, MOND provides superior fits to the extended, flat portions of spiral rotation curves without such tuning. Additionally, MOND sidesteps the core-cusp problem inherent in simulations, as the dynamics are governed entirely by distributed baryons, naturally producing the observed smooth, cored profiles in galactic centers without unresolved cuspy halos.

Dwarf Galaxies and Low-Surface-Brightness Systems

In Modified Newtonian Dynamics (MOND), dwarf galaxies and low-surface-brightness (LSB) systems represent regimes where internal accelerations often approach or fall below the critical acceleration scale a_0 \approx 1.2 \times 10^{-10} m s^{-2}, amplifying the theory's modifications to Newtonian gravity. These low-mass systems challenge the dark matter paradigm due to discrepancies in predicted versus observed dynamics, such as the core-cusp problem and diversity in rotation curves. MOND addresses these by relying solely on baryonic matter to generate the required gravitational fields, without invoking unseen components. The external field effect (EFE) plays a key role here, as the pervasive gravitational influence from nearby massive galaxies can suppress MONDian enhancements in isolated dwarfs, altering their internal dynamics. A primary prediction of MOND for dwarf spheroidal galaxies is a floor in the line-of-sight velocity dispersion, typically around 3–7 km s^{-1}, imposed by the EFE from the host galaxy's field. This arises because the EFE limits the MOND boost when internal accelerations are comparable to the external field strength, preventing arbitrarily low dispersions in satellites. For tidal streams around dwarfs, MOND predicts asymmetric tails due to the nonlinear nature of the theory, where leading and trailing arms experience different effective gravities influenced by the host's field. Observational evidence supports these predictions in specific systems. The Sculptor dwarf spheroidal galaxy, a satellite with a of approximately $10^7 M_\odot, exhibits a velocity dispersion profile consistent with MOND using only its baryonic content, requiring no and yielding a mass-to-light ratio near unity. Similarly, fits to a sample of 27 dwarf and LSB galaxies, including gas-rich systems like DDO 154 and NGC 2366, reproduce observed rotation curves using baryonic mass distributions alone, with reduced \chi^2 values comparable to or better than models. Recent N-body simulations in the QUMOND formulation (2024) demonstrate that MOND predicts asymmetric tidal tails around low-mass systems. MOND naturally resolves the core-cusp issue in these systems, as the observed cored density profiles (central densities \sim 10^7 - 10^8 M_\odot kpc^{-3}) emerge from baryonic distributions without the need for cuspy dark matter halos predicted by \LambdaCDM simulations. The diversity in dwarf rotation curves—ranging from slowly rising profiles in gas-poor systems to steeper rises in others at fixed maximum velocities—is explained by variations in baryonic morphology and star formation history, rather than ad hoc adjustments to dark halo properties. A 2024 study using Modified Lagrangian Dynamics (MLD), a formulation akin to QUMOND, confirms N-body asymmetries in low-mass systems like dwarfs, aligning with these observations and highlighting MOND's predictive power for tidal features.

Additional Tests and Phenomena

Gravitational Lensing

In Modified Newtonian Dynamics (MOND), gravitational lensing requires a relativistic extension, such as tensor-vector-scalar (TeVeS) gravity, to properly describe photon geodesics and deflection angles. In TeVeS, the lensing potential arises from contributions of scalar and vector fields, where the scalar field modifies the deflection angle compared to general relativity, while the vector field influences time delays but not the deflection itself. This formulation allows MOND to predict lensing effects without dark matter by enhancing the gravitational potential in weak acceleration regimes. For idealized models like isothermal spheres, TeVeS predicts gravitational lensing that is approximately twice the strength of the Newtonian prediction due to the deeper MOND potential, leading to larger Einstein radii and higher lensing cross-sections. This enhancement is particularly pronounced in the deep-MOND limit, where accelerations fall below the critical threshold a_0 \approx 1.2 \times 10^{-10} m s^{-2}, making lensing a sensitive probe of modified on galactic and scales. Observational evidence supports MOND's lensing predictions in specific cases, such as the Bullet Cluster (1E 0657-558), where attempts have been made to reproduce the observed mass distribution from weak lensing using the baryonic content combined with the "phantom dark matter" effect—an effective density arising from the nonlinear MOND potential that mimics collisionless matter without actual dark particles—but MOND struggles to fully account for the separation of lensing peaks from baryonic gas without invoking additional components, presenting a challenge for the theory. Detailed modeling shows that the offset between the hot gas (traced by X-rays) and the lensing peaks aligns with some MOND expectations when accounting for the collision dynamics of galaxies and intracluster medium, though requiring non-baryonic particles like massive neutrinos in many formulations. MOND has also demonstrated successful fits to numerous strong gravitational lens systems on galactic scales, reproducing observed image positions, magnifications, and mass profiles using baryonic matter distributions alone, in agreement with surveys like CASTLES. These fits, spanning dozens of lenses, highlight MOND's ability to match lensing data without halos, though cluster-scale lenses remain more challenging due to higher accelerations approaching the Newtonian regime. Predictions in MOND include stronger lensing effects in weak-field environments compared to Newtonian gravity, which can be tested through time delays between multiple images in systems. In TeVeS, these delays are altered by the contribution, potentially yielding Hubble constant measurements differing from by up to 20-30% for certain interpolating functions, offering a pathway for empirical verification with ongoing observations. A key limitation of pure Newtonian MOND is its inability to define photon propagation without a relativistic framework; TeVeS and similar extensions are essential for accurate lensing calculations, though they introduce free parameters that must be tuned to match both dynamics and lensing.

Wide Binary Stars and Other Solar System Scales

In Modified Newtonian Dynamics (MOND), wide binary star systems serve as natural laboratories for testing gravitational modifications at low accelerations, where the theory predicts enhanced effective gravity leading to relatively higher orbital velocities or wider separations compared to Newtonian expectations for accelerations below the critical threshold a_0 \approx 1.2 \times 10^{-10} m s^{-2}. Analyses of wide binaries with separations of 2–30 kAU, where internal accelerations approach or fall below a_0, indicate that MONDian effects would manifest as orbital velocities exceeding Newtonian predictions by factors of up to \sqrt{2}. Recent observations from the Gaia DR3 catalog, spanning data releases and analyses from 2023 to 2025, yield mixed results; some studies provide marginal evidence (2–3σ) supporting MOND-like enhancements in low-acceleration regimes using Bayesian 3D velocity modeling that isolates low-acceleration regimes (g_N \lesssim 10^{-9} m s^{-2}), while others favor Newtonian dynamics after improved modeling of systematics like triple-star contamination and projection biases. These results, derived from samples of thousands of candidate wide binaries within 300 pc, highlight the ongoing debate, with critical reviews as of 2025 emphasizing the need for further refinement to resolve discrepancies. As of November 2025, the interpretation remains controversial, though systematic effects require careful modeling. At solar system scales, MOND effects are generally negligible due to internal accelerations far exceeding a_0, transitioning smoothly to the Newtonian regime where the external galactic field dominates via the external field effect (EFE). However, lunar laser ranging (LLR) experiments, which measure Earth-Moon distances to millimeter precision over decades, impose tight constraints on MOND parameters by probing subtle EFE-induced perturbations in the lunar orbit. Similarly, planetary ephemerides such as INPOP, constructed from ranging data to spacecraft and natural satellites, limit variations in the effective gravitational constant and a_0 to within 10–20% of empirical values, confirming that MOND-compliant formulations must reproduce observed orbital dynamics without significant deviations. These tests highlight MOND's consistency at high accelerations while allowing perturbations, such as secular changes in eccentricity, to be quantified for further validation. Other intermediate-scale phenomena potentially align with MOND predictions. MOND has been proposed to explain a previously reported discrepancy in Saturn's perihelion through the from the galactic tidal field, which induces a distant-mass-like without invoking unseen like ; numerical integrations yield rates consistent with older observations, distinguishing MOND from standard Newtonian models that underpredict the effect in those datasets. Flyby anomalies, unexplained velocity jumps of several mm s^{-1} during spacecraft encounters (e.g., Galileo, NEAR), have been tentatively linked to MOND-inspired modifications of that alter effective at low speeds, reproducing observed latitude-dependent shifts within . Recent proposals leverage binary pulsar timing arrays to probe the MOND-Newtonian transition regime at scales bridging solar system and galactic dynamics. By analyzing pulse arrival times from systems like PSR B1913+16, where orbital periods decay under combined internal and external fields, these observations could constrain EFE manifestations and a_0 with sub-percent precision using facilities like MeerKAT and SKA, offering a direct test of MOND's interpolating function in the $10^{-10} to $10^{-8} m s^{-2} range.

Criticisms and Alternatives

Dark Matter Paradigm Comparison

The standard ΛCDM model, which incorporates (CDM) and a , explains galactic dynamics by assuming that non-baryonic dominates the gravitational potential through extended halos surrounding visible baryonic matter. This paradigm successfully accounts for the flat rotation curves of spiral galaxies by attributing the excess velocity to the cumulative mass of these invisible halos, whose density profiles are typically modeled using functions like the Navarro-Frenk-White (NFW) profile. In contrast, Modified Newtonian Dynamics (MOND) dispenses with dark matter entirely, instead altering Newton's law of gravity—or more precisely, the inertial response to it—at accelerations below a universal threshold a_0 \approx 1.2 \times 10^{-10} m s^{-2}, thereby generating the observed dynamics from baryonic matter alone. A primary advantage of MOND lies in its : it requires only the single universal parameter a_0 alongside the known distribution to predict and fit the rotation curves of thousands of across a wide range of luminosities and morphologies, achieving typical residuals of around 15% or better in comprehensive datasets. models, however, demand multiple free parameters per —often four or more, including , scale , concentration, and sometimes —to match the same , as the unseen must be tuned individually for each system. Additionally, MOND derives the (BTFR) as a direct consequence of its formalism, linking a 's total M_b to its flat rotation V_f via M_b \propto V_f^4 / a_0 without invoking , a scaling that holds empirically over five decades in . Recent analyses of dwarf (as of October 2025) further indicate that MOND fails to explain their internal gravitational fields without additional . The paradigm demonstrates strong successes on cosmological scales, accurately reproducing the acoustic peaks in the (CMB) spectrum observed by Planck and the hierarchical formation of large-scale structure in simulations like IllustrisTNG, where dark matter clustering seeds formation. Yet, on sub-galactic scales, it encounters tensions such as the cusp-core problem, where ΛCDM simulations predict steeply rising central dark matter densities (cusps) in dwarf galaxies, but kinematic observations reveal flatter cored profiles, and the missing satellites problem, wherein models forecast hundreds of luminous satellites around galaxies like the , but only dozens are detected. Philosophically, MOND represents a fundamental revision to gravitational theory, addressing mass discrepancies as an intrinsic property of low-acceleration regimes akin to how modifies Newtonian at high speeds, whereas the approach introduces a new, undetected particle species whose galactic-scale distribution seems contrived to resolve discrepancies without altering core physics. Rotation curves remain a central arena for this debate, as MOND's predictions stem solely from observed baryons, offering a unified explanation for their shapes and amplitudes.

Challenges in Galaxy Clusters

One of the primary challenges for Modified Newtonian Dynamics (MOND) arises in galaxy clusters, where the theory struggles to account for the observed dynamical masses without invoking significant additional non-baryonic mass. Observations indicate that galaxy clusters require approximately 5 to 10 times more total mass than the inferred baryonic content to maintain and virialization, whereas standard MOND formulations predict only about a factor of 2 enhancement in gravitational effects due to the modified acceleration law. This discrepancy is evident from measurements of virial masses derived from velocity dispersions and observations of intracluster gas, which reveal a persistent " " problem in MOND. For instance, analyses of relaxed clusters using temperature profiles and assumptions show that MOND underpredicts the total by factors of 3 to 5 compared to baryonic estimates, necessitating extra components beyond standard baryons. A particularly stringent test comes from colliding clusters like the , where the separation of baryonic gas (detected via emission) from the (inferred from weak lensing) favors a collisionless component that decouples during the merger, a that MOND cannot naturally reproduce without ad hoc modifications. Efforts to address these issues within MOND include incorporating massive neutrinos as an additional mass component or invoking the external , which provides a mild boost to internal dynamics but remains insufficient to close the . However, even with , MOND falls short in explaining cluster lensing and dynamics, as classical neutrinos alone cannot account for the required mass without exceeding cosmological bounds. Recent studies, including a 2025 analysis of mass profiles from survey, confirm that MOND still underpredicts the missing by a factor of ~4 after accounting for baryons and potential extensions, highlighting ongoing failures in this regime. Similarly, investigations into extended MOND variants like emergent MOND (EMOND) or hybrid MOND plus models show that additional scalar fields or particles are needed, yet these do not fully resolve the dynamical mismatches in clusters.

Cosmological and Large-Scale Issues

MOND in Cosmology

Modified Newtonian dynamics (MOND) faces significant challenges in cosmological contexts due to the absence of a natural cold dark matter (CDM) component, which is central to the standard ΛCDM model for explaining the large-scale structure of the universe. In pure MOND frameworks, the lack of CDM leads to altered perturbation growth rates, with baryonic matter alone driving structure formation more efficiently through enhanced low-acceleration gravity, but resulting in a power spectrum that deviates from observations, typically predicting insufficient power on large scales during the linear regime. This discrepancy arises because MOND modifies the Poisson equation in a way that affects the evolution of density perturbations differently from Newtonian gravity, particularly in the expanding universe where the Friedmann equations must be adapted without non-baryonic matter. To address these issues, relativistic extensions of MOND, such as the tensor-vector-scalar (TeVeS) theory, incorporate scalar and vector fields to recover in high-acceleration limits while producing MONDian behavior at low accelerations. These theories aim to mimic ΛCDM cosmology by adjusting field parameters to replicate the history and early-universe dynamics, but they encounter difficulties in reproducing the detailed anisotropies of the (CMB). For instance, TeVeS struggles to match the position and amplitude of acoustic peaks in the CMB power spectrum without introducing additional components, as the scalar field's evolution alters photon-baryon interactions during recombination. MOND cosmologies predict a higher fraction compared to ΛCDM, as all gravitational effects on large scales are attributed to without invoking , leading to tensions with constraints on the density. Additionally, these models face issues with (BAO), where the modified growth function suppresses the observed scale of acoustic features, and the integrated Sachs-Wolfe (ISW) effect, which is altered by the non-standard evolution of gravitational potentials, resulting in mismatches with late-time CMB-large-scale structure correlations. Reviews up to 2023 indicate that pure MOND remains incompatible with full cosmological datasets, viable primarily through hybrid models incorporating or modified early-universe physics, though persistent tensions with data highlight ongoing challenges in achieving a consistent framework. Brief mention of TeVeS provides a for cosmological applications, but detailed derivations are beyond standard implementations.

Recent Observational Constraints (Post-2023)

In 2025, analyses of wide stars using data from the mission provided evidence for MOND-like behavior at low accelerations, though results remain debated with some studies favoring Newtonian . A Bayesian 3D modeling approach applied to a sample of wide binaries revealed a where relative velocities exceed Newtonian predictions by approximately 30-40% in the low-acceleration regime, corresponding to high for modified dynamics. This result builds on prior DR3 studies but incorporates full 3D velocities, strengthening the case for acceleration-dependent in solar-system-like environments. Galaxy cluster observations in 2025 imposed tighter constraints on MOND variants. An August study examined lensing and dynamical data from clusters, finding that pure MOND struggles to reproduce mass profiles without additional components, though extensions like emergent MOND (EMOND) or MOND plus dark matter remain viable but require fine-tuning. Earlier reviews highlighted MOND's successes in explaining rotation curves and wide binaries but noted persistent failures in clusters, where predicted velocities fall short by factors of 2-3 compared to observations. Tidal tail asymmetries in open star clusters also aligned with MOND predictions in 2025 simulations. Direct N-body models incorporating quasi-linear MOND (QUMOND) reproduced observed leading-trailing tail imbalances in low-mass clusters, such as those seen in data, whereas standard models predict symmetric tails. This asymmetry arises from the external field effect in MOND, providing a distinct testable signature absent in Newtonian with halos. Overall, post-2023 observations present a balanced picture for MOND: it rules out pure interpretations in select dwarf galaxies by better matching velocity dispersions without invoking unseen mass, yet clusters continue to pose significant challenges, necessitating hybrid models. Ongoing debates, including conflicting wide binary analyses and 2025 reviews on MOND versus , underscore the need for further tests.

Proposals for Future Tests

Laboratory and Astrophysical Experiments

Laboratory experiments have been proposed to test Modified Newtonian Dynamics (MOND) by probing potential violations of the near the characteristic acceleration scale a_0 \approx 10^{-10} m/s², where MOND effects become prominent in the transition regime between Newtonian and deep-MOND gravity. Torsion balance setups, such as Cavendish-type experiments, can detect MOND-induced corrections to gravitational forces through nonlinear dynamics and enhanced displacement amplitudes in freely falling systems. These tests aim to distinguish between MOND variants, including and modified gravity interpretations, by measuring small accelerations in controlled environments. Proposed free-fall laboratory configurations, including space-based platforms, suggest sensitivity to equivalence principle violations arising from MOND's nonlinear field equations. Atom interferometry offers another promising avenue for laboratory verification of MOND in weak gravity fields, leveraging coherent atomic wave packets to measure relative accelerations with high precision. In such setups, MOND predicts larger-than-expected phase shifts due to modified inertial or gravitational responses at accelerations below a_0. These experiments could probe the , where MOND formulations may introduce subtle violations not present in . Current proposals indicate feasibility in microgravity environments, though no definitive detections have been reported as of November 2025. On astrophysical scales, observations of wide binary stars using data from the mission provide statistical tests of MOND through relative velocity measurements at low accelerations. Recent analyses of Gaia DR3 data, incorporating realistic triple system modeling, favor Newtonian dynamics over MOND predictions, with better fits for models in orbital anomalies at separations of 0.1–1 pc. These results challenge MOND but highlight ongoing statistical tests in isolated systems. Pulsar timing arrays, monitoring pulsars for timing residuals, are proposed to search for signatures of relativistic MOND extensions like TeVeS, such as deviations in correlations influenced by tensor-scalar modifications. While no MOND-specific signals have been confirmed, ongoing arrays like NANOGrav and EPTA offer potential sensitivity to such effects in the nanohertz regime. MOND predicts specific anomalies in the at accelerations around $10^{-10} m/s², manifesting as position-dependent violations in the external field effect, where the gravitational response varies with the ambient field strength. Unlike models, MOND anticipates no self-interaction signals from undetected particles in laboratory or small-scale astrophysical probes, as it modifies directly without invoking non-baryonic . This absence serves as a distinguishing testable prediction, contrasting with self-interacting scenarios that expect scattering signatures in dense environments. As of 2025, proposals for the include investigations of MOND-relativistic extensions through signatures differing from , such as altered propagation speeds or polarization modes in quasi-linear formulations. These build on precursor tests with and aim to detect MOND effects in the intermediate regime during mission operations planned for the 2030s.

Predicted Signatures for Verification

In galaxy clusters, Modified Newtonian Dynamics (MOND) predicts a distinct baryonic bias between the masses inferred from dynamical measurements, such as galaxy velocity dispersions, and those derived from gravitational lensing, arising from the nonlinear Poisson equation and the external field effect (EFE) that suppresses internal dynamics relative to an . This bias manifests as dynamical estimates requiring approximately 20-50% more baryonic mass than lensing-inferred totals to match observations, providing a falsifiable signature testable with high-precision weak lensing surveys. The space telescope, operational since 2023 and expected to map over 10^5 strong lensing systems and billions of galaxies for weak lensing by 2030, will enable direct comparisons of these mass estimators in relaxed clusters, potentially confirming or refuting MOND if the predicted discrepancy exceeds ΛCDM expectations by factors of 2-3 in total mass-to-baryon ratios. In cosmological contexts, MOND and its relativistic extensions, such as Tensor-Vector-Scalar (TeVeS) gravity, forecast unique patterns in () polarization differing from ΛCDM due to altered scalar perturbations and modified initial conditions that enhance early structure growth. Specifically, TeVeS predicts a suppression of the low-multipole (ℓ < 10) EE polarization power spectrum by up to 20% compared to ΛCDM, alongside boosted tensor modes from vector field contributions, observable in future high-sensitivity polarization data from missions like LiteBIRD or the Simons Observatory. Additionally, MOND-inspired cosmologies anticipate deviations in cosmic void statistics, with voids exhibiting 10-30% larger underdensities and fewer small voids (radii < 50 Mpc) than in standard models, stemming from stronger gravitational clustering on large scales; these can be probed via galaxy surveys like DESI or Euclid's photometric redshift tomography. The EFE briefly influences these predictions by modulating void wall dynamics in low-density regions. Within the solar neighborhood, MOND anticipates enhanced anomalous accelerations during spacecraft flybys of or other bodies, driven by transient drops into the low-acceleration regime (a < a_0 ≈ 10^{-10} m/s²) and the EFE from the galactic field, yielding velocity changes of order 1-10 mm/s depending on perigee altitude and incoming asymptote. Future missions involving repeated flybys, such as proposed extensions to solar probes, could detect these boosts, which scale as δv / v_in ≈ (a_0 / g_peri)^{1/2} × (v_rot / v_in), falsifying if absent at the 0.1 mm/s level. At high redshifts ( > 6), MOND predicts brighter and more massive galaxies than ΛCDM due to amplified in the early universe's higher mean density, where MOND effects marginally enhance formation rates by factors of 1.5-2, leading to functions exceeding observations by 0.5 mag in the rest-frame UV for M_* > 10^{10} M_⊙ systems. This signature arises from faster baryonic infall and reduced suppression of small-scale power. As of 2025, (JWST) observations of Lyman-break galaxies at z ≈ 10-15 reveal higher number densities of massive systems than predicted by ΛCDM, consistent with MOND expectations and observable with NIRCam deep fields, , and Roman Space Telescope surveys to quantify efficiencies in these protogalaxies.

References

  1. [1]
    A modification of the Newtonian dynamics as a possible alternative to the hidden mass hypothesis.
    - **Key Postulate of MOND**: Milgrom proposes modifying Newtonian dynamics as an alternative to hidden mass, introducing a new regime for low accelerations.
  2. [2]
    Modified Newtonian Dynamics, an Introductory Review - arXiv
    Jan 20, 2006 · In this paper, I will review the basics of MOND and its ability to explain observations without the need of dark matter.
  3. [3]
    Modified Newtonian Dynamics as an Alternative to Dark Matter - arXiv
    Apr 30, 2002 · We review the phenomenological success of MOND on scales ranging from dwarf spheroidal galaxies to superclusters, and demonstrate that the ...
  4. [4]
    [1404.0531] A historical perspective on Modified Newtonian Dynamics
    Apr 1, 2014 · Abstract:I review the history and development of Modified Newtonian Dynamics (MOND) beginning with the phenomenological basis as it existed ...
  5. [5]
    Rotation of the Andromeda Nebula from a Spectroscopic Survey of ...
    Velocities from this line indicate a rapid rotation in the nucleus, rising to a maximum circular velocity of V = 225 km at R = 400 pc, and falling to a deep ...
  6. [6]
    A modification of the Newtonian dynamics as a possible alternative ...
    A modification of the Newtonian dynamics as a possible alternative to the hidden mass hypothesis. Milgrom, M. Abstract. The author considers the possibility ...
  7. [7]
    The MOND paradigm of modified dynamics - Scholarpedia
    Mar 20, 2025 · MOND, conceived in mid 1981, was enunciated in January 1982 in a series of three papers, published, after some struggle, in 1983 (Milgrom, 1983a ...
  8. [8]
    http://www.scholarpedia.org/article/The_MOND_paradigm_of_modified_dynamics
  9. [9]
    Why did the dark matter hypothesis supersede modified gravity in ...
    Jul 15, 2025 · Abstract page for arXiv paper 2507.11598: Why did the dark matter hypothesis supersede modified gravity in the 1980s?
  10. [10]
    https://arxiv.org/abs/2507.11598
  11. [11]
    https://ui.adsabs.harvard.edu/abs/1990A&ARv...2....1S/abstract
  12. [12]
    https://ui.adsabs.harvard.edu/abs/1977A&A....54..661T/abstract
  13. [13]
    https://ui.adsabs.harvard.edu/abs/1937ApJ....86..217Z/abstract
  14. [14]
    Modified Newtonian Dynamics (MOND): Observational ... - arXiv
    Dec 16, 2011 · Here, we first review a few outstanding challenges for the dark matter interpretation of mass discrepancies in galaxies, purely based on observations.
  15. [15]
    External field effect of modified Newtonian dynamics in the Solar ...
    This so-called external field effect has been recently shown to imply the existence of an anomalous quadrupolar correction, along the direction of the external ...
  16. [16]
    MOND - A Pedagogical Review - M. Milgrom
    THE MODIFIED DYNAMICS. This modified dynamics, MOND, introduces a constant with the dimensions of an acceleration, 0, and posits that standard Newtonian ...
  17. [17]
    [1404.7661] MOND theory - arXiv
    Apr 30, 2014 · A general account of MOND theory is given. I start with the basic tenets of MOND, which posit departure from standard dynamics in the limit of low acceleration.
  18. [18]
    Milgrom, Modified Newtonian Dynamics - IOP Science
    The Astrophysical Journal, 571:L81-L83, 2002 June 1 © 2002. The American Astronomical Society. All rights reserved. Printed in U.S.A.. Do Modified Newtonian ...
  19. [19]
    MOND
    For M of the order of a galactic mass, the transition would take place at around 10 kpc (but a galaxy is not a central point mass), thus suggesting that at ...
  20. [20]
    Negligible MOND effects on the orbits of planets - IOPscience
    Sep 17, 2025 · First proposed in 1983, Modified Newtonian Dynamics (MOND) provides an alternative picture to dark matter theory.
  21. [21]
    Quasi-linear formulation of MOND - Oxford Academic
    These theories are now added to the non-linear Poisson formulation of MOND propounded a quarter century ago by Bekenstein & Milgrom (1984), to which it is ...Missing: AQUAL | Show results with:AQUAL
  22. [22]
    Relativistic gravitation theory for the MOND paradigm - astro-ph - arXiv
    Mar 30, 2004 · We develop a relativistic MOND inspired theory which resolves these problems. In it gravitation is mediated by metric, a scalar field and a 4-vector field, all ...
  23. [23]
    Relativistic gravitation theory for the modified Newtonian dynamics ...
    Oct 13, 2004 · In the last two decades, Milgrom's modified Newtonian dynamics (MOND) paradigm [7–9] has gained recognition as a successful scheme for unifying ...<|control11|><|separator|>
  24. [24]
    Theoretical Aspects of Gravitational Lensing in TeVeS - arXiv
    Following Bekenstein's work, we investigate the phenomena of gravitational lensing including deflection angles, lens equations and time delay. We find that the ...
  25. [25]
    Testing Bekenstein's relativistic Modified Newtonian Dynamics with ...
    Recently, a fully relativistic, generally covariant version of MOND has been proposed, TeVeS (Bekenstein 2004), which passes standard local and cosmological ...
  26. [26]
    Effects of gravitational lensing and companion motion on the binary ...
    Mar 6, 2006 · Here we calculate the effect of retardation due to the companion's motion on various time delays in pulsar binaries, including the Shaipro delay ...Missing: TeVeS | Show results with:TeVeS
  27. [27]
    [gr-qc/0506021] Scalar-Tensor-Vector Gravity Theory - arXiv
    Jun 3, 2005 · A covariant scalar-tensor-vector gravity theory is developed which allows the gravitational constant G, a vector field coupling \omega and the vector field ...Missing: key | Show results with:key
  28. [28]
    A nonlocal metric formulation of MOND - ADS
    We study a class of nonlocal, but causal, covariant and conserved field equations for the metric. Although nonlocal, these equations do not seem to possess ...
  29. [29]
    Nonlocal metric realizations of MOND - Canadian Science Publishing
    Because nonlocal MOND equations (42) are fixed once the function f(Z) has been defined, one can subject the model to meaningful tests by studying its response ...
  30. [30]
    Determining Cosmology for a Nonlocal Realization of MOND - arXiv
    Aug 28, 2016 · Abstract:We numerically determine the cosmological branch of the free function in a nonlocal metric-based modification of gravity which ...
  31. [31]
    Open Star Clusters and Their Asymmetrical Tidal Tails - IOPscience
    Jul 19, 2024 · MOND and the MLD Code. Modified Newtonian dynamics (MOND) is a nonrelativistic theory that generalizes Newtonian gravitation and is nonlinear ...
  32. [32]
    TESTING MODIFIED NEWTONIAN DYNAMICS WITH ROTATION ...
    We have presented MOND fits for a sample of 27 dwarf and LSB galaxies. MOND is remarkably successful at predicting the general shape of the rotation curves in ...
  33. [33]
    Asymmetry of the tidal tails of open star clusters in direct N-body ...
    Nov 20, 2024 · It is found that the tidal tails of a low-mass star cluster are populated asymmetrically in the MLD-treatment, very similar to the QUMOND simulations of the ...
  34. [34]
    Gravitational lensing in modified Newtonian dynamics
    Lacking a relativistic analogue, however, MOND makes no definite predictions about cosmology or photon propagation.
  35. [35]
    Modified Newtonian Dynamics (MOND): Observational ...
    Sep 7, 2012 · First of all, an interpolating function must be chosen, then one can determine the value of a0 by fitting, all at once, a sample of high-quality ...
  36. [36]
    [astro-ph/0606216] Can MOND take a bullet? Analytical ... - arXiv
    Jun 9, 2006 · Can MOND take a bullet? Analytical comparisons of three versions of MOND beyond spherical symmetry. Authors:Garry W. Angus, Benoit Famaey, ...
  37. [37]
    Can MOND take a bullet? Analytical comparisons of three versions ...
    G. W. Angus, B. Famaey, H. S. Zhao, Can MOND take a bullet? Analytical comparisons of three versions of MOND beyond spherical symmetry, Monthly Notices of ...
  38. [38]
    MOND and the lensing fundamental plane: no need for dark matter ...
    Bolton et al. have derived a mass-based fundamental plane using photometric and spectroscopic observations of 36 strong gravitational lenses. The lensing allows ...
  39. [39]
    Hubble constant, lensing, and time delay in Te Ve S
    doi:10.1017/S1743921312021692 Hubble constant, lensing, and time delay in TeVeS ... isothermal lens model (see Witt et al. 2000). This is expected, since ...Missing: twice | Show results with:twice
  40. [40]
    Testing Bekenstein's Relativistic MOND gravity with Lensing Data
    Dec 16, 2005 · We propose to use multiple-imaged gravitational lenses to set limits on gravity theories without dark matter, specificly TeVeS (Bekenstein 2004) ...
  41. [41]
    Low-acceleration Gravitational Anomaly from Bayesian 3D Modeling ...
    These results show that a gravitational anomaly is evident for gN ≲ 10−9 m s−2 and Γ in the MOND regime (≲10−9.5 m s−2) agrees with the first-tier prediction (Γ ...
  42. [42]
    Strong constraints on the gravitational law from Gaia DR3 wide ...
    Hydrodynamical MOND simulations of M33 (Banik et al. 2020) were motivated by difficulties in understanding why it is weakly barred, bulgeless, and has a two ...Missing: streams | Show results with:streams
  43. [43]
    [2504.07569] Wide Binaries from Gaia DR3 : testing GR vs MOND ...
    Apr 10, 2025 · We provide an updated test for modifications of gravity from a sample of wide-binary stars from GAIA DR3, and their sky-projected relative velocities.
  44. [44]
    3D velocity analysis of wide binaries supports modified gravity at low ...
    May 27, 2025 · New method of measuring gravity with 3D velocities of wide binary stars is developed and confirms modified gravity at low acceleration.
  45. [45]
    On the MOND External Field Effect in the Solar System
    Aug 6, 2025 · Precise measurements in the Solar System would place constraints on MOND ... The Lunar Laser Ranging (LLR) experiment provides precise ...
  46. [46]
    [PDF] Lunar system constraints on the modified theories of gravity - arXiv
    The leading effect of MOND is changing the ratio of the 'Earth-Moon distance' to the 'LAGEOS satellites-Earth distance'.
  47. [47]
    https://iopscience.iop.org/article/10.3847/1538-4357/adce09
  48. [48]
    (PDF) The perihelion precession of Saturn, planet X/Nemesis and ...
    Aug 7, 2025 · In this paper we confirm the existence of this effect by a numerical integration of the MOND equation in the presence of an external field, and ...
  49. [49]
    [PDF] The Perihelion Precession of Saturn, Planet X/Nemesis and MOND
    Oct 7, 2009 · perihelion precession of Saturn as a real physical effect needing explanation. Finally, let us note that a complementary approach to the.
  50. [50]
    [PDF] Modelling the flyby anomalies using a modification of inertia. - arXiv
    Jun 29, 2008 · Three of the flyby anomalies were reproduced within error bars, and the theory explains their recently-observed dependence on the latitude.
  51. [51]
    Gravity experiments with radio pulsars | Living Reviews in Relativity
    Jul 22, 2024 · In Sect. 3, we present an outline of the pulsar timing technique and describe the relativistic effects that have been seen in binary pulsars, ...
  52. [52]
    MeerKAT Pulsar Timing Array parallaxes and proper motions
    The astrometric, period, spin-down, DM, and (where necessary) binary parameters of every pulsar are described in a timing model. Using the pulsar timing ...Missing: MOND | Show results with:MOND
  53. [53]
    The Baryonic Tully-Fisher Relation of Gas Rich Galaxies as a Test of ...
    Jul 14, 2011 · The Baryonic Tully-Fisher Relation (BTFR) is an empirical relation between baryonic mass and rotation velocity in disk galaxies.
  54. [54]
    Review of solutions to the Cusp-core problem of the $Λ$CDM Model
    Sep 28, 2022 · This review aims at proposing to the field an overview of the Cusp-core problem, including a discussion of its advocated solutions.
  55. [55]
    [1009.4505] Notes on the Missing Satellites Problem - arXiv
    Sep 23, 2010 · The Missing Satellites Problem (MSP) broadly refers to the overabundance of predicted Cold Dark Matter (CDM) subhalos compared to satellite galaxies known to ...
  56. [56]
    On the nature of the missing mass of galaxy clusters in MOND - arXiv
    Oct 3, 2024 · Modified Newtonian Dynamics (MOND) has long been known to fail in galaxy clusters, implying a residual missing mass problem for clusters in this context.
  57. [57]
    X-ray group and cluster mass profiles in MOND - Oxford Academic
    The result is that MOND cannot as yet explain the mass discrepancy in X-ray emitting clusters of galaxies, and especially in their cores, while the ...
  58. [58]
    New constraints on modified Newtonian dynamics from galaxy clusters
    For eight nearby and relaxed clusters, we confirmed that MOND alone is not able to explain the missing mass problem in clusters of galaxies. Almost 80 per cent ...2 Mond Dynamical Masses · 3.3 The Baryonic Mass In... · 5 DiscussionMissing: challenges | Show results with:challenges<|separator|>
  59. [59]
    Bullet Cluster and MOND - dark matter - Physics Stack Exchange
    Oct 3, 2015 · The Argument seems to be that most (>90%) of the baryonic mass in these clusters is in the form of X-ray emitting gas. Therefore the gravity lensing should ...Do alternate theories for Dark Matter (like MOND) explain its effect ...Do the Bullet Cluster remnants prove that dark matter consists out of ...More results from physics.stackexchange.comMissing: TeVeS phantom
  60. [60]
    Arguments against dark matter in the Bullet Cluster fall apart - Medium
    Jul 16, 2024 · It's largely through weak gravitational lensing that mass reconstruction of the mass distributions within galaxy clusters is carried out, and ...Missing: TeVeS phantom<|control11|><|separator|>
  61. [61]
    MOND plus classical neutrinos are not enough for cluster lensing
    Abstract. Clusters of galaxies offer a robust test bed for probing the nature of dark matter that is insensitive to the assumption of the gravity theories.Missing: extensions | Show results with:extensions
  62. [62]
    [PDF] New constraints on modified Newtonian dynamics from galaxy clusters
    MOND must invoke neutrinos to represent the main component that account for the missing mass problem in clusters. Key words: galaxies: clusters: general ...
  63. [63]
    Nature of the missing mass of galaxy clusters in MOND
    Modified Newtonian dynamics (MOND) has long been known to fail in galaxy clusters, implying a residual missing mass problem for clusters in this context.Missing: limitations | Show results with:limitations
  64. [64]
    Galaxy Cluster Constraints on Extensions of Modified Gravity
    Aug 1, 2025 · In this work, we investigate the viability of EMOND and MOND + DM in the context of galaxy clusters using both observational and theoretical ...
  65. [65]
    [2502.09373] Low-Acceleration Gravitational Anomaly from ... - arXiv
    Feb 13, 2025 · Recent statistical analyses of wide binaries have been performed only with sky-projected relative velocities v_p in the pairs. A new method ...
  66. [66]
    Asymmetry in the tidal tails of open star clusters from direct N-body ...
    We found that the tidal tails of a low-mass star cluster are populated asymmetrically in the MLD treatment, similarly to what is seen in QUMOND simulations of ...
  67. [67]
    Modified Newtonian Dynamics: Observational Successes and Failures
    May 31, 2025 · Modified Newtonian Dynamics: Observational Successes and Failures. May 2025 ... Observational Constraints on Scalar-Tensor Theories of ...
  68. [68]
    Evidence for modified Newtonian dynamics from Cavendish-type ...
    Feb 18, 2020 · MOND corrections for a torsion pendulum ... Torsion pendulum experiments are incredible sensitive and have been used to test violations ...
  69. [69]
    Can MOND type hypotheses be tested in a free fall laboratory ... - arXiv
    May 28, 2013 · These experiments may also be able to test potential violations of the strong equivalence principle by MOND and to distinguish between its two ...
  70. [70]
    Non-Einsteinian gravitational waves in pulsar timing array correlations
    In this paper, we investigate the nature of the SGWB by considering correlations beyond the Hellings–Downs (HD) curve of Einstein's general relativity.
  71. [71]
    Testing Modified Newtonian Dynamics with LISA Pathfinder
    LISA Pathfinder will be able to probe the intermediate MOND regime, i.e. the transition between deep MOND and Newtonian gravity. We present robust estimates of ...
  72. [72]
    Galaxy clusters in Milgromian dynamics: Missing matter, hydrostatic ...
    At larger radii, the fit results are less satisfactory but the combination of the MOND external field effect and hydrostatic bias (quantified as 10%–40%) can ...
  73. [73]
    [PDF] Euclid - ESA Science & Technology
    Euclid derives the mass function of galaxy clusters (in combination with eROSITA, Planck and SZ telescopes), and finds over 105 strong lensing systems.
  74. [74]
    Testing alternative theories of dark matter with the CMB | Phys. Rev. D
    Sep 26, 2008 · We propose a method to study and constrain modified gravity theories for dark matter using CMB temperature anisotropies and polarization.
  75. [75]
    (PDF) Cosmic voids in modified gravity scenarios - ResearchGate
    Aug 6, 2025 · Other work emphasized the connection between void statistics and cosmological ... (MOND), the characteristic acceleration scale of the ...
  76. [76]
    Modified Newtonian Dynamics as an Alternative to the Planet Nine ...
    We show that a modified gravity theory known as modified Newtonian dynamics (MOND) provides an alternative explanation for the anomalies using the well- ...