Curiel, Erik (2020) Schematizing the Observer and the Epistemic Content of Theories. [Preprint]

Curiel, Erik (2019) Framework Confirmation by Newtonian Abduction. [Preprint]

Curiel, Erik (2018) What Is a Black Hole? [Preprint]

Curiel, Erik (2018) On Geometric Objects, the Non-Existence of a Gravitational Stress-Energy Tensor, and the Uniqueness of the Einstein Field Equation. [Preprint]

Curiel, Erik (2018) Framework Confirmation by Newtonian Abduction. [Preprint]

Curiel, Erik (2016) On the Existence of Spacetime Structure. The British Journal for the Philosophy of Science.

Curiel, Erik (2016) A Simple Proof of the Uniqueness of the Einstein Field Equation in All Dimensions. [Preprint]

Curiel, Erik (2016) Kinematics, Dynamics, and the Structure of Physical Theory. [Preprint]

Curiel, Erik (2015) A Weyl-Type Theorem for Geometrized Newtonian Gravity. [Preprint]

Curiel, Erik (2015) A Weyl-Type Theorem for Geometrized Newtonian Gravity. [Preprint]

Curiel, Erik (2015) On the Existence of Spacetime Structure. [Preprint]

Curiel, Erik (2014) A Primer on Energy Conditions. [Preprint]

Curiel, Erik (2014) Are Classical Black Holes Hot or Cold? [Preprint]

Curiel, Erik (2014) Classical Black Holes Are Hot. [Preprint]

Curiel, Erik (2014) If Metrical Structure Were Not Dynamical, Counterfactuals in General Relativity Would Be Easy. [Preprint]

Curiel, Erik (2014) Measure, Topology and Probabilistic Reasoning in Cosmology. [Preprint]

Curiel, Erik (2014) Why Rigid Designation Cannot Stand on Scientific Ground. [Preprint]

Curiel, Erik (2011) On the Propriety of Physical Theories as a Basis for Their Semantics. [Preprint]

Curiel, Erik (2011) Classical Mechanics is Lagrangian; It Is Not Hamiltonian. [Preprint]

Curiel, Erik (2009) On Tensorial Concomitants and the Non-Existence of a Gravitational Stress-Energy Tensor. [Preprint]

Curiel, Erik (2009) General Relativity Needs No Interpretation. In: UNSPECIFIED.

Curiel, Erik (2005) On the Formal Consistency of Theory and Experiment, with Applications to Problems in the Initial-Value Formulation of the Partial-Differential Equations of Mathematical Physics. [Preprint]