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Y-DNA Haplogroup • Paternal Lineage

R1B1A1B1A1A2C1A5B1A

Y-DNA Haplogroup R1B1A1B1A1A2C1A5B1A

~14,000 years ago
West Eurasia
1 subclades
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Chapter I

The Story

The journey of Y-DNA haplogroup R1B1A1B1A1A2C1A5B1A

Origins and Evolution

Y-DNA haplogroup R1b1a1b1a1a2c1a5b1a is a highly derived subclade within the broader R1b paternal lineage, one of the major Y-chromosome branches of western Eurasia. Because it sits deep within the R1b phylogeny, its formation likely occurred after the initial diversification of western Eurasian hunter-gatherer and early farming populations, probably in the Late Upper Paleolithic to Early Holocene transition. A reasonable estimate for its origin is around 14 thousand years ago, consistent with the broader parent-clade context and the long time depth required for such a downstream branch to accumulate.

This lineage is best understood as a rare survival lineage: it likely persisted in small demographically buffered populations through the Mesolithic, Neolithic, and later Bronze Age restructurings that transformed much of the R1b landscape. Unlike the more famous western European R1b expansions associated with later prehistoric population growth, this subclade appears to have remained at low frequency, preserving an older regional signal within the broader R1b radiation.

Subclades

As a terminal or near-terminal downstream branch in a complex R1b lineage, R1b1a1b1a1a2c1a5b1a may have few or no widely sampled surviving sister branches in current datasets. Its phylogenetic importance lies in connecting the deeper parent clade to more localized descendant lines, helping reconstruct how rare paternal lineages survived repeated prehistoric bottlenecks and migrations.

In practical population-genetic terms, such a branch often indicates one of three patterns: regional continuity, small-scale founder effects, or survival in isolated refugial populations. Given the parent context, the most plausible interpretation is that this lineage has endured across multiple regions of western Eurasia without undergoing a major explosive expansion.

Geographical Distribution

Current evidence and the parent-clade context suggest a scattered distribution across western Eurasia, with detections in populations from the British Isles, France, Iberia, the Low Countries, Italy, the Balkans, the Caucasus, Anatolia, the Levant, North Africa, and some Central Asian or steppe-related groups. Such a broad but sparse pattern is typical of an old lineage that has been carried by successive layers of population movement rather than by a single dominant demographic event.

The highest likelihood of detection is in regions where R1b diversity is relatively high and where ancient population layering has been substantial. However, because this is a rare subclade, its apparent distribution is likely influenced by sampling density and database coverage; it may exist at very low frequency in additional nearby populations that have not yet been deeply tested.

Historical and Cultural Significance

Rare downstream branches of R1b are valuable for reconstructing the fine-scale history of paternal lineages in western Eurasia. While broad R1b expansions are often associated with Late Neolithic and Bronze Age demographic transformations, a lineage like R1b1a1b1a1a2c1a5b1a may preserve traces of pre-expansion regional ancestry or later persistence in isolated subpopulations.

It is reasonable to associate this lineage, at least indirectly, with cultural horizons that shaped the distribution of R1b overall, including Mesolithic western Eurasian groups, Neolithic farming communities, and later Bronze Age mobility networks. The lineage may not be diagnostic of any one archaeology-defined culture, but its presence within regions influenced by Bell Beaker, Yamnaya-derived steppe ancestry, and other post-Neolithic dispersals makes it informative for understanding how old lineages were absorbed into changing societies.

Population-Genetic Interpretation

From a population genetics perspective, this haplogroup is significant because it illustrates how deep paternal diversity can survive in the shadow of larger expansions. Many Y-chromosome lineages become rare not because they disappeared entirely, but because they were outcompeted demographically by later founder events. The scattered occurrence of this subclade suggests a pattern of persistence at low effective population size, with occasional drift-mediated survival in multiple locales.

Because it is so far downstream, R1b1a1b1a1a2c1a5b1a should be interpreted cautiously: present-day distribution does not necessarily reveal a single homeland, and its ancestry may reflect complex prehistoric layering across West Eurasia. Nevertheless, its age and phylogenetic position make it an important marker of the deep internal structure of R1b.

Conclusion

R1b1a1b1a1a2c1a5b1a is a rare, deeply branching Y-DNA lineage within western Eurasian R1b. Its broad but sparse distribution points to long-term survival across multiple prehistoric periods, making it a useful marker for studying regional continuity, drift, and the fine structure of paternal ancestry in West Eurasia.

Key Points

  • Origins and Evolution
  • Subclades
  • Geographical Distribution
  • Historical and Cultural Significance
  • Population-Genetic Interpretation
Chapter II

Tree & Relationships

Phylogenetic context and subclades

Evolution Path

This haplogroup's evolutionary journey from its earliest ancestor to the present.

Steps Haplogroup Age Estimate Archaeology Era Time Passed Immediate Descendants Tested Modern Descendants Ancient Connections
1 R1B1A1B1A1A2C1A5B1A Current ~14,000 years ago 🏹 Mesolithic 14,000 years 1 1 0
2 R1B1A1B1A1A2C1A5B1 ~14,000 years ago 🏹 Mesolithic 14,000 years 1 1 0
3 R1B1A1B1A1A2C1A5B ~14,000 years ago 🏹 Mesolithic 14,000 years 1 1 0
4 R1B1A1B1A1A2C1A5 ~14,000 years ago 🏹 Mesolithic 14,000 years 2 19 0
5 R1B1A1B1A1A2C1A ~14,000 years ago 🏹 Mesolithic 14,000 years 6 331 9
6 R1B1A1B1A1A2C1 ~14,000 years ago 🏹 Mesolithic 14,000 years 2 581 0
7 R1B1A1B1A1A2C ~14,000 years ago 🏹 Mesolithic 14,000 years 1 582 111
8 R1B1A1B1A1A2 ~14,000 years ago 🏹 Mesolithic 14,000 years 6 916 0
9 R1B1A1B1A1A ~14,000 years ago 🏹 Mesolithic 14,000 years 4 1,254 70
10 R1B1A1B1A1 ~14,000 years ago 🏹 Mesolithic 14,000 years 1 1,292 0
11 R1B1A1B1A ~14,000 years ago 🏹 Mesolithic 14,000 years 2 1,295 15
12 R1B1A1B1 ~18,000 years ago 🏹 Mesolithic 18,000 years 2 1,529 0
13 R1B1A1B ~18,000 years ago 🏹 Mesolithic 18,000 years 2 1,655 31
14 R1B1A1 ~18,000 years ago 🏹 Mesolithic 18,000 years 2 1,657 0
15 R1B1A ~18,000 years ago 🏹 Mesolithic 18,000 years 2 3,825 39
16 R1B1 ~18,000 years ago 🏹 Mesolithic 18,000 years 2 3,967 0
17 R1b ~20,000 years ago 🏹 Mesolithic 20,000 years 2 4,036 126
Chapter III

Where in the World

Geographic distribution and modern presence

Place of Origin

West Eurasia

Modern Distribution

The populations where Y-DNA haplogroup R1b1a1b1a1a2c1a5b1a is found include:

  1. Irish and British populations
  2. French, Iberian, and Low Countries populations
  3. Italian and Balkan populations
  4. Caucasus and Anatolian populations
  5. Levantine and North African populations
  6. Some Central Asian and steppe-related populations

Regional Presence

Western Europe High
Northern Europe Moderate
Southwestern Europe Low
Northwestern Europe High
Northern Africa Low
North America (diaspora) Low
Southern Europe Low
Eastern Europe Low
Western Asia Low
Central Asia Low
CHAPTER IV

When in Time

Your haplogroup in the context of human history

~20k years ago

Last Glacial Maximum

Peak of the last ice age, populations isolated

~14k years ago

Haplogroup R1B1A1B1A1A2C1A5B1A

Your Y-DNA haplogroup emerged in West Eurasia

West Eurasia
~10k years ago

Neolithic Revolution

Agriculture begins, settled communities form

~5k years ago

Bronze Age

Metalworking, writing, and early civilizations

~3k years ago

Iron Age

Iron tools, expanded trade networks

~2k years ago

Classical Antiquity

Greek and Roman civilizations flourish

Present

Present Day

Modern era

Your Haplogroup
Historical Era
Chapter IV-B

Linked Cultures

Ancient cultures associated with Y-DNA haplogroup R1B1A1B1A1A2C1A5B1A

Cultural Heritage

These ancient cultures have been linked to haplogroup R1B1A1B1A1A2C1A5B1A based on matching ancient DNA samples from archaeological excavations. The presence of this haplogroup in these cultures provides insights into the migrations and population movements of populations carrying this haplogroup.

British Iron Age British Late Bronze Age British Late Iron Age Early British Iron Age Irish Bronze Age Late Iron Age British Middle Iron Age British Roman Croatia Scottish Bronze Age
Culture assignments are based on archaeological context of ancient DNA samples and may represent regional associations during specific time periods.
Chapter V

Sample Catalog

3 subclade carriers of haplogroup R1B1A1B1A1A2C1A5B1A (no exact R1B1A1B1A1A2C1A5B1A samples sequenced yet)

3 / 3 samples
Portrait Sample Country Era Date Culture Y-DNA Match
Portrait of ancient individual I0160 from United Kingdom, dated 166 BCE - 116 CE
I0160
United Kingdom Iron Age England 166 BCE - 116 CE British Iron Age R1b1a1b1a1a2c1a5b1a1a Downstream
Portrait of ancient individual I12778 from United Kingdom, dated 381 BCE - 203 BCE
I12778
United Kingdom Middle Iron Age England 381 BCE - 203 BCE Middle Iron Age British R1b1a1b1a1a2c1a5b1a1a Downstream
Portrait of ancient individual I16611 from United Kingdom, dated 401 BCE - 208 BCE
I16611
United Kingdom Middle Iron Age England 401 BCE - 208 BCE Middle Iron Age British R1b1a1b1a1a2c1a5b1a1a2 Downstream
Chapter VI

Carrier Distribution Map

Geographic distribution of 3 ancient DNA samples (direct and subclade carriers of R1B1A1B1A1A2C1A5B1A)

Subclade carrier
Time Period Filter
All Time Periods
Showing all samples
Chapter VII

Temporal Distribution

Distribution of carriers across archaeological periods

Chapter VIII

Geographic Distribution

Distribution by country of origin (direct and subclade carriers shown by default)

Chapter IX

Country × Era Distribution

Cross-tabulation of carrier countries and archaeological periods (direct and subclade carriers shown by default)

Data

Data & Provenance

Source information and data quality

Last Updated 2026-06-17
Confidence Score 50/100
Coverage Low
Data Source

We use the latest phylotree for YDNA haplogroup classification and data.