RESEARCH BASE

Search 3,721 documents across 34 fields — every claim tier-rated by evidence

3,721 documents 34 sections 43,623 citations 34,854 keywords indexed 4 evidence tiers

3,633 are the core, quality-scored corpus (34 lettered sections — see How We Work); the remaining 88 are cross-corpus synthesis documents (68 InterDocs, 12 Connections, 8 Theories) also indexed here.

2,331 results for "Type Ia supernova" — page 106 of 117

V_4_03 Mathematics & Information

V_4_03 — Geometric Probability and Buffon's Needle

Geometric probability assigns probabilities to random geometric events — needle drops, random points in regions, random lines intersecting figures — formalizing questions that blend chance with spatial structure. Buffon'

geometric probability Buffon needle Bertrand paradox integral geometry stochastic geometry random convex sets
V_4_12 Credible Mathematics & Information

V_4_12 — Mathematical Modeling: Abstraction, Validation, and Prediction

Mathematical modeling — the art and science of translating real-world phenomena into mathematical language, analyzing the resulting equations, and interpreting the results back in terms of the original problem — is the p

mathematical modeling abstraction validation prediction simulation differential equations
V_3_01 Mathematics & Information

V_3_01 — Statistics & Probability: Pascal to Bayes

Probability and statistics — the mathematics of uncertainty — emerged as formal disciplines from the Pascal-Fermat correspondence (1654) on the "problem of points" (how to divide stakes in an interrupted game of chance),

statistics probability Pascal Fermat Bayes Bernoulli
V_3_08 Mathematics & Information

V_3_08 — Fractal Geometry: Self-Similarity Across Scales

Fractal geometry, developed primarily by Benoit Mandelbrot (1975-1982), studies shapes with self-similar structure at multiple scales — coastlines, fern leaves, blood vessel networks, galaxy distributions, and financial

fractals fractal geometry self-similarity Mandelbrot set Julia sets fractal dimension
V_3_05 Mathematics & Information

V_3_05 — Linear Algebra: Matrices, Vectors, and Transformations

Linear algebra is arguably the most practically important branch of mathematics, underpinning quantum mechanics, machine learning, computer graphics, engineering, statistics, and nearly every computational science. It st

linear algebra matrices vectors vector spaces eigenvalues eigenvectors
V_3_11 Mathematics & Information

V_3_11 — Mathematical Optimization: Linear Programming, Convex Methods, and Gradient Descent

Mathematical optimization — finding the best solution from a set of feasible alternatives — is one of the most practically impactful branches of mathematics, with applications spanning logistics, finance, engineering, ma

mathematical optimization linear programming simplex method convex optimization gradient descent stochastic gradient descent
V_3_02 Mathematics & Information

V_3_02 — Graph Theory & Network Mathematics

Graph theory — the mathematics of networks, connections, and relationships — began with Euler's Königsberg bridge problem (1736) and has become one of the most broadly applicable branches of mathematics, with direct rele

graph theory network Euler Königsberg Erdős random graph
V_3_13 Mathematics & Information

V_3_13 — Nonlinear Dynamics and Bifurcation Theory

Nonlinear dynamics studies systems whose behavior is not proportional to their inputs — where small changes can produce large effects, qualitative transitions, and deterministic chaos. While linear systems superpose pred

nonlinear dynamics bifurcation chaos theory Lorenz attractor strange attractor Lyapunov exponent
V_2_06 Mathematics & Information

V_2_06 — Set Theory & Foundations Crisis: Cantor, Russell, Gödel

The foundations crisis (c. 1895–1936) was the most profound intellectual upheaval in the history of mathematics — revealing that the discipline's logical underpinnings were far more fragile than anyone had imagined.

set theory foundations Cantor Russell paradox Gödel incompleteness
V_2_21 Verified Mathematics & Information

V_2_21 — Topology Applications in Science

Topology — the branch of mathematics concerned with properties preserved under continuous deformation (stretching, bending, twisting, but not tearing or gluing) — has transformed from an abstract mathematical discipline

topology topological invariants Euler characteristic knot theory persistent homology topological data analysis
V_2_17 Credible Mathematics & Information

V_2_17 — Homological Algebra: Chain Complexes, Exact Sequences, and Derived Functors

Homological algebra provides a powerful, abstract framework for studying algebraic structures — groups, rings, modules, sheaves — by analyzing chain complexes (sequences of abelian groups or modules connected by homomorp

homological algebra chain complex exact sequence homology cohomology derived functor
V_2_02 Mathematics & Information

V_2_02 — Topology & Knot Theory: Celtic Knots to DNA

Topology — the study of properties preserved under continuous deformation (stretching, bending, but not tearing or gluing) — originated with Euler's solution to the Königsberg bridge problem (1736) and evolved into one o

topology knot theory Euler Königsberg bridges Celtic knotwork DNA topology
V_2_07 Mathematics & Information

V_2_07 — Formal Logic: Aristotle to Turing

Formal logic — the systematic study of valid inference — spans 2,400 years from Aristotle's syllogistic (c. 350 BCE) to Turing's computation theory (1936). Aristotle's Organon established the syllogism as the fundamental

logic formal logic Aristotle syllogism Boolean algebra Frege
V_2_15 Mathematics & Information

V_2_15 — Galois Theory and Field Extensions

Galois theory, developed by Évariste Galois (1811-1832) in the last years of his tragically short life, is one of the great triumphs of abstract algebra — a theory connecting field extensions to group theory that definit

Galois theory field extension polynomial roots solvability by radicals quintic equation group theory
V_2_11 Mathematics & Information

V_2_11 — Abstract Algebra: Groups, Rings, and Fields

Abstract algebra is the study of algebraic structures — sets equipped with operations satisfying specific axioms — that generalize familiar arithmetic operations to reveal deep structural patterns across mathematics and

abstract algebra group theory ring theory field theory symmetry Galois theory
V_2_03 Mathematics & Information

V_2_03 — History of Algebra: Al-Khwarizmi to Group Theory

Algebra — the generalization of arithmetic to unknown quantities and their relationships — has a 4,000-year documented history, from Babylonian equation-solving tablets (c. 1800 BCE) through Brahmagupta's Indian treatise

algebra Al-Khwarizmi equation quadratic cubic Brahmagupta
V_2_12 Mathematics & Information

V_2_12 — Algebraic Geometry

Algebraic geometry — the study of geometric objects defined by polynomial equations — is one of the most central and technically demanding branches of modern mathematics, connecting algebra, geometry, topology, and numbe

algebraic geometry variety scheme polynomial equation projective space elliptic curve
A_1_00 Foundations

A_1_00 — Mesopotamian Near Eastern: Subfolder Summary

A_4_00 Foundations

A_4_00 — Asian Indigenous Eastern: Subfolder Summary

A_4_22 Verified Foundations

A_4_22 — Puranas: Hindu Cosmological Encyclopedia

The Puranas (Purāṇa, "ancient, old") are a vast corpus of Hindu sacred literature comprising 18 Mahāpurāṇas ("Great Puranas") and 18 Upapurāṇas ("Secondary Puranas"), totaling hundreds of thousands of verses (the Skanda

Puranas Hindu cosmology cosmic cycles yugas kalpas manvantaras