Below is a broad, structured set of **(subject, predicate, object)** triples about the theory of evolution. I’ll keep them in triple form as much as possible, while covering core ideas, evidence, mechanisms, history, examples, and implications.

## Core definition
- (theory of evolution, explains, how populations of organisms change over time)
- (evolution, refers to, descent with modification)
- (evolution, operates on, heritable variation)
- (evolution, acts on, populations rather than individual organisms)
- (evolution, produces, biological diversity)
- (common ancestry, is a central idea of, evolution)
- (natural selection, is a major mechanism of, evolution)
- (mutation, creates, new genetic variation)
- (gene flow, moves, alleles between populations)
- (genetic drift, changes, allele frequencies by chance)
- (nonrandom mating, influences, genetic structure of populations)

## Basic biological units
- (DNA, stores, genetic information)
- (genes, influence, heritable traits)
- (alleles, are, variants of genes)
- (genotype, refers to, an organism’s genetic makeup)
- (phenotype, refers to, observable traits)
- (heritable traits, can be passed from, parents to offspring)
- (variation, exists within, populations)
- (variation, is necessary for, natural selection)

## Natural selection
- (natural selection, favors, traits that increase reproductive success)
- (natural selection, acts on, phenotypes)
- (natural selection, indirectly changes, allele frequencies)
- (fitness, means, reproductive success)
- (adaptive traits, increase, fitness)
- (environment, influences, which traits are favored)
- (selection pressure, drives, differential survival and reproduction)
- (survival, is not the same as, fitness)
- (reproduction, is a key component of, fitness)
- (selection, can be, directional, stabilizing, or disruptive)

## Other mechanisms of evolution
- (mutation, introduces, new alleles)
- (recombination, reshuffles, genetic variation)
- (sexual reproduction, increases, variation among offspring)
- (gene flow, reduces, differences between populations)
- (genetic drift, has stronger effects in, small populations)
- (founder effect, is a form of, genetic drift)
- (bottleneck effect, is a form of, genetic drift)
- (mutation rate, varies among, genes and organisms)
- (selection, is often opposed by, drift)
- (drift, can fix, neutral or even mildly harmful alleles)

## Speciation
- (speciation, is the formation of, new species)
- (reproductive isolation, promotes, speciation)
- (geographic isolation, can lead to, allopatric speciation)
- (sympatric speciation, occurs without, geographic separation)
- (prezygotic barriers, prevent, mating or fertilization)
- (postzygotic barriers, reduce, viability or fertility of hybrids)
- (hybrid sterility, prevents, gene flow between species)
- (species, are often defined by, reproductive isolation)
- (speciation, results from, accumulated genetic divergence)

## Patterns of evolution
- (descent with modification, explains, similarities among organisms)
- (homologous structures, indicate, common ancestry)
- (analogous structures, arise from, convergent evolution)
- (convergent evolution, produces, similar traits in unrelated lineages)
- (adaptive radiation, produces, many species from a common ancestor)
- (co-evolution, occurs when, species influence each other’s evolution)
- (microevolution, refers to, small-scale evolutionary change)
- (macroevolution, refers to, large-scale evolutionary patterns and processes)
- (gradualism, describes, slow evolutionary change over long time periods)
- (punctuated equilibrium, describes, long periods of stasis with rapid change)

## Evidence from fossils
- (fossils, record, past life)
- (fossil record, shows, change over time)
- (transitional fossils, show, intermediate forms)
- (stratigraphy, helps determine, relative ages of fossils)
- (radiometric dating, estimates, absolute ages of rocks and fossils)
- (extinction, is observed in, the fossil record)
- (extinct species, are species that no longer, exist)
- (horse evolution, is documented by, fossil series)
- (archaeopteryx, shows, a mix of dinosaur and bird traits)
- (Tiktaalik, shows, features intermediate between fish and tetrapods)

## Evidence from comparative anatomy
- (comparative anatomy, compares, body structures across species)
- (homology, supports, common ancestry)
- (vestigial structures, are reduced remnants of, ancestral traits)
- (vestigial organs, can still have, residual or altered functions)
- (embryology, can reveal, shared developmental patterns)
- (developmental biology, supports, evolutionary relationships)
- (shared genetic code, supports, common ancestry)

## Evidence from genetics and molecular biology
- (DNA sequence similarity, supports, relatedness among species)
- (protein similarity, reflects, evolutionary relatedness)
- (molecular phylogenetics, reconstructs, evolutionary relationships)
- (phylogenetic trees, represent, hypotheses of ancestry and descent)
- (mutations, accumulate over time in, lineages)
- (pseudogenes, provide evidence for, common ancestry)
- (endogenous retroviruses, can mark, shared ancestry)
- (chromosome similarities, can indicate, relatedness)
- (human chromosome 2, is consistent with, fusion of two ancestral ape chromosomes)

## Evidence from biogeography
- (biogeography, studies, geographic distribution of organisms)
- (island species, often show, unique evolutionary histories)
- (continental isolation, promotes, divergent evolution)
- (Darwin’s finches, illustrate, adaptive radiation)
- (Australia, has many endemic species due to, long geographic isolation)
- (species distribution, reflects, evolution and Earth history)

## Human evolution
- (humans, are a product of, evolution)
- (humans, share a common ancestor with, other apes)
- (Homo sapiens, evolved in, Africa)
- (human evolution, involved, bipedalism)
- (human evolution, involved, larger brains)
- (human evolution, involved, tool use and culture)
- (Neanderthals, were, close relatives of modern humans)
- (genetic evidence, shows, interbreeding between Homo sapiens and Neanderthals)
- (human populations, continue to evolve under, selection and drift)

## Historical development of evolutionary theory
- (Charles Darwin, proposed, natural selection)
- (Alfred Russel Wallace, independently developed, natural selection)
- (Darwin, published, On the Origin of Species)
- (Gregor Mendel, discovered, the basic laws of inheritance)
- (modern synthesis, united, Darwinian selection and Mendelian genetics)
- (population genetics, provided, mathematical foundations for evolution)
- (Theodosius Dobzhansky, helped develop, the modern synthesis)
- (Ernst Mayr, contributed to, the biological species concept and modern synthesis)
- (Julian Huxley, popularized, the modern synthesis)

## Common misconceptions
- (evolution, does not mean, progress toward perfection)
- (evolution, does not have, a predetermined goal)
- (humans, did not evolve from, modern monkeys)
- (humans and modern monkeys, share, a common ancestor)
- (natural selection, does not always produce, the “best” possible trait)
- (evolution, is not the same as, individual adaptation during a lifetime)
- (acquired traits, are generally not inherited as a rule of, evolution)
- (evolution, is supported by, multiple independent lines of evidence)

## Key concepts in population genetics
- (allele frequency, measures, how common an allele is in a population)
- (Hardy-Weinberg equilibrium, describes, a non-evolving population model)
- (departure from Hardy-Weinberg equilibrium, suggests, evolutionary change)
- (selection coefficient, measures, strength of selection)
- (effective population size, influences, strength of genetic drift)
- (polymorphism, refers to, multiple forms within a population)
- (adaptation, is a trait shaped by, selection)
- (neutral evolution, involves, changes not driven by selection)

## Evolution and ecology
- (ecology, influences, evolution)
- (environmental change, can alter, selective pressures)
- (predation, can drive, evolution of defenses)
- (parasites, can drive, host evolution)
- (competition, can drive, niche differentiation)
- (niche, affects, which traits are advantageous)
- (sexual selection, favors, traits that increase mating success)
- (mate choice, can shape, evolution of ornamental traits)

## Evolution of complexity
- (complex traits, can evolve by, small incremental changes)
- (exaptation, is a trait co-opted for, a new function)
- (feathers, likely evolved for, functions before flight)
- (eye evolution, demonstrates, gradual improvement through intermediates)
- (multicellularity, evolved multiple times in, different lineages)
- (evolution, can produce, increased complexity, simplicity, or no net change)

## Antibiotic resistance and real-time evolution
- (antibiotic resistance, evolves through, natural selection)
- (bacteria, can evolve resistance quickly because of, short generation times)
- (overuse of antibiotics, increases, selection for resistant strains)
- (pesticide resistance, is an example of, evolution by selection)
- (viruses, evolve rapidly due to, high mutation rates and short generation times)

## Theoretical scope and limits
- (evolutionary theory, explains, the diversity of life and its changes)
- (evolutionary theory, does not address directly, the origin of life)
- (abiogenesis, studies, the origin of life from nonliving chemistry)
- (evolutionary biology, overlaps with, genetics, ecology, paleontology, and molecular biology)
- (evolutionary theory, is scientific because it is, testable and evidence-based)
- (evolutionary hypotheses, can be, supported or refuted by data)

## Broad implications
- (evolution, helps explain, antibiotic resistance)
- (evolution, helps explain, viral variation)
- (evolution, helps explain, biodiversity)
- (evolution, helps explain, extinction and adaptation)
- (evolution, informs, medicine, agriculture, and conservation)
- (conservation genetics, uses, evolutionary principles)
- (selective breeding, applies, evolutionary principles in domestication)

## Very concise summary triples
- (evolution, is, change in heritable traits over generations)
- (natural selection, is, differential reproductive success)
- (mutation, is, the source of new genetic variation)
- (common ancestry, is, the unifying explanation for shared features of life)
- (speciation, is, the origin of new species)
- (fossils, genetics, anatomy, and biogeography, support, evolution)

If you want, I can also convert this into:
1. a **much larger exhaustive triple list**,  
2. **only strict subject–predicate–object RDF-style triples**, or  
3. a **knowledge graph JSON/CSV format**.
