Holocene Calendar - Wikipedia

Calendar era that uses 10,000 BC as 1 HE "Holocene era" redirects here. For the geological epoch, see Holocene. "Human Era" redirects here. For the album, see Human Era (album).

The Holocene calendar, also known as the Holocene Era or Human Era (HE), is a year numbering system that adds exactly 10,000 years to the currently dominant (AD/BC or CE/BCE) numbering scheme, placing its first year near the beginning of the Holocene geological epoch and the Neolithic Revolution, when humans shifted from a hunter-gatherer lifestyle to agriculture and fixed settlements. The current year by the Gregorian calendar, AD 2026, is 12026 HE in the Holocene calendar. The HE scheme was first proposed by Cesare Emiliani in 1993 (11993 HE),[1] though similar proposals to start a new calendar at the same date had been put forward decades earlier.[2][3] Emiliani thereby dismissed his original proposal to align the era with the 7980-year Julian cycles, i.e. start with the epoch in 4713 BCE (5288 HE).[1]

Overview

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Cesare Emiliani's proposal for a calendar reform sought to solve a number of alleged problems with the current Anno Domini era, also called the Common Era, which numbers the years of the commonly accepted world calendar. These issues include:

• The Anno Domini era has no year "zero", with 1 BC followed immediately by AD 1, making calculation of time spans difficult.
• The years BC/BCE are counted down when moving from past to future, complicating the calculation of timespans further.
• The birth date of Jesus is a less universally relevant epoch event than the approximate beginning of the Holocene.
• The Anno Domini era is based on the erroneous or contentious estimates of the birth year of Jesus of Nazareth. The era places Jesus's birth year in AD 1, but modern scholars have determined that it is more likely that he was born in or before 4 BC.[4] Emiliani argued that replacing the contested date with the approximate beginning of the Holocene makes more sense.

Instead, HE uses the "beginning of human era" as its epoch, arbitrarily defined as 10,000 BC and denoted year 1 HE, so that AD 1 matches 10,001 HE.[1] This is a rough approximation of the start of the current geologic epoch, the Holocene (the name means entirely recent). The motivation for this is that human civilization (e.g. the first settlements, agriculture, etc.) is believed to have arisen within this time. Emiliani later proposed that the start of the Holocene should be fixed at the same date as the beginning of his proposed era.[5]

Benefits

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Human Era proponents claim that it makes for easier geological, archaeological, dendrochronological, anthropological and historical dating, as well as that it bases its epoch on an event more universally relevant than the birth of Jesus. All key dates in human history can then be listed using a simple increasing date scale with smaller dates always occurring before larger dates. Another gain is that the Holocene Era starts before the other calendar eras, so it could be useful for the comparison and conversion of dates from different calendars.

Accuracy

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When Emiliani discussed the calendar in a follow-up article in 1994, he mentioned that there was no agreement on the date of the start of the Holocene epoch, with estimates at the time ranging between 12,700 and 10,970 years BP.[5] Since then, scientists have improved their understanding of the Holocene on the evidence of ice cores and can now more accurately date its beginning. A consensus view was formally adopted by the IUGS in 2013, placing its start at 11,700 years before 2000 (9701 BC), about 300 years more recent than the epoch of the Holocene calendar.[6]

Equivalent proposals

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In 1924 Gabriel Deville proposed the use of Calendrier nouveau de chronologie ancienne (CNCA), which would start 10,000 years before AD 1, which is identical to Emiliani's much later proposal.[2]

Since 1929, Dievturība adherents use Latviskā ēra (the Latvian Era) which begins at the same point; this coincides with the first inhabitants’ influx to the territory of present Latvia (10500–10047 BCE). According to the Latvian Era, 12026 is written for 2026 CE. Detailed explanation of Latvian Era by Ernests Brastiņš was first published in 1934.[7][8][9]

In 1963 E.R. Hope proposed the use of Anterior Epoch (AE), which also begins at the same point.[3]

Conversion

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Conversion from Julian or Gregorian calendar years to the Human Era can be achieved by adding 10,000 to the AD/CE year. The present year, 2026, can be transformed into a Holocene year by adding the digit "1" before it, making it 12,026 HE. Years BC/BCE are converted by subtracting the BC/BCE year number from 10,001.

Calendar epochs and milestones in the Holocene calendar

Gregorian year	ISO 8601	Holocene year	Event
10002 BC	−10001	−1 HE
10001 BC	−10000	0 HE
10000 BC	−9999[a]	1 HE	Epoch of the Holocene calendar era. Equivalent to 11949 Before Present (BP)
9701 BC	−9700	300 HE	End of the Pleistocene and beginning of the Holocene (geological epoch),[6] equivalent to 11650 BP
4714 BC	−4713	5287 HE	Epoch of the Julian day system: Julian day 0 starts at Greenwich noon on January 1, 4713 BC of the proleptic Julian calendar, which is November 24, 4714 BC in the proleptic Gregorian calendar[10]: 10  This is equivalent to 6,663 BP.
3761 BC	−3760	6240 HE	Beginning of the Anno Mundi calendar era in the Hebrew calendar[10]: 11
3102 BC	−3101	6899 HE	Beginning of the Kali Yuga in Hindu cosmology[11]
2250 BC	−2249	7751 HE	Beginning of the Meghalayan, the current and latest of the three stages in the Holocene.[12][13]
45 BC	−0044	9956 HE	Introduction of the Julian calendar
1 BC	0000	10000 HE	Year zero at ISO 8601
1 AD	0001	10001 HE	Beginning of the Common Era and Anno Domini, from the estimate by Dionysius Exiguus
622	0622	10622 HE	Migration of Muhammad from Mecca to Medina, starting the Islamic calendar[14][15] at 1 AH
1582	1582	11582 HE	Introduction of the Gregorian calendar[10]: 47
1912	1912	11912 HE	Epoch of the Juche[16] and Republic of China calendars[17]
1950	1950	11950 HE	Epoch of the Before Present dating scheme[18]: 190
1960	1960	11960 HE	UTC Epoch
1970	1970	11970 HE	Unix Epoch[19]
1993	1993	11993 HE	Publication of the Holocene calendar
2026	2026	12026 HE	Current year
10000	+10000	20000 HE

1. ^ Emiliani states his proposal would set "the beginning of the human era at 10,000 BC" but does not mention the Julian or Gregorian calendar.[1]

See also

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• After the Development of Agriculture, a calendar system that adds 8000 years to the Common Era.
• Anno Lucis, a calendar system that adds 4000 years to the Common Era.
• Before Present, the notation most widely used today in scientific literature for dates in prehistory.
• Calendar reform

References

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1. ^ a b c d Emiliani, Cesare (1993). "Correspondence – calendar reform". Nature. 366 (6457): 716. Bibcode:1993Natur.366..716E. doi:10.1038/366716b0.
2. ^ a b Naudin, Claude (2001). De temps en temps: Histoires de calendrier [From time to time: Calendar stories]. Le Grand Livre du Mois. ISBN 2-7028-4735-8.
3. ^ a b Hope, E.R. (1963). "The arithmetical reform of the calendar, Part I". Journal of the Royal Astronomical Society of Canada. 57 (1): 14–23. Bibcode:1963JRASC..57...14H.
4. ^ Rahner, Karl (2004). Encyclopedia of theology: a concise Sacramentum mundi. Continuum. p. 732. ISBN 978-0-86012-006-3. Archived from the original on July 27, 2020. Retrieved October 8, 2020.
5. ^ a b Emiliani, Cesare (1994). "Calendar reform for the year 2000". Eos. 75 (19): 218. Bibcode:1994EOSTr..75..218E. doi:10.1029/94EO00895.
6. ^ a b Walker, Mike; Jonsen, Sigfus; Rasmussen, Sune Olander; Popp, Trevor; Steffensen, Jørgen-Peder; Gibbard, Phil; Hoek, Wim; Lowe, John; Andrews, John; Björck, Svante; Cwynar, Les C.; Hughen, Konrad; Kershaw, Peter; Kromer, Bernd; Litt, Thomas; Lowe, David J.; Nakagawa, Takeshi; Newnham, Rewi; Schwander, Jacob (2009). "Formal definition and dating of the GSSP (Global Stratotype Section and Point) for the base of the Holocene using the Greenland NGRIP ice core, and selected auxiliary records" (PDF). Journal of Quaternary Science. 24 (1): 3–17. Bibcode:2009JQS....24....3W. doi:10.1002/jqs.1227. Archived (PDF) from the original on 2013-11-04.
7. ^ Nastevičs, Uģis (2022). "Latvian Dievturība: A Study of Rituals, Their Sacred Space and Texts". Dievturu Vēstnesis. 43 (3): 2467–2481. ISSN 2661-5088.
8. ^ Nastevičs, Uģis (2022). Latviešu dievturība un japāņu šintō. Rituāli, to sakrālā telpa un teksti salīdzinošā aspektā. Puzuri. ISBN 9789934906725.
9. ^ Brastiņš, Ernests (1934). "Latviskais laiks". Labietis. 5: 72–73. ISSN 0456-9571.
10. ^ a b c Dershowitz, Nachum; Reingold, Edward M. (2008). Calendrical Calculations (3rd ed.). Cambridge University Press. ISBN 978-0-521-70238-6.
11. ^ See: Matchett, Freda, "The Puranas", p 139 and Yano, Michio, "Calendar, astrology and astronomy" in Flood, Gavin, ed. (2003). Blackwell companion to Hinduism. Blackwell Publishing. ISBN 978-0-631-21535-6.
12. ^ "ICS chart containing the Quaternary and Cambrian GSSPs and new stages (v 2018/07) is now released!". Archived from the original on February 19, 2020. Retrieved February 6, 2019.
13. ^ Conners, Deanna (September 18, 2018). "Welcome to the Meghalayan age". Archived from the original on February 2, 2019. Retrieved February 6, 2019.
14. ^ Aisha El-Awady (2002-06-11). "Ramadan and the Lunar Calendar". Islamonline.net. Archived from the original on 2006-12-14. Retrieved 2006-12-16.
15. ^ Hakim Muhammad Said (1981). "The History of the Islamic Calendar in the Light of the Hijra". Ahlul Bayt Digital Islamic Library Project. Archived from the original on 2011-06-10. Retrieved 2006-12-16.
16. ^ Hy-Sang Lee (2001). North Korea: A Strange Socialist Fortress. Greenwood Publishing Group. p. 220. ISBN 978-0-275-96917-2.
17. ^ Endymion Wilkinson (2000). Chinese History: A Manual. Harvard Univ Asia Center. pp. 184–185. ISBN 978-0-674-00249-4.
18. ^ Currie Lloyd A (2004). "The Remarkable Metrological History of Radiocarbon Dating [II]" (PDF). Journal of Research of the National Institute of Standards and Technology. 109 (2): 185–217. doi:10.6028/jres.109.013. PMC 4853109. PMID 27366605. Archived from the original (PDF) on 2010-12-06. Retrieved 2018-06-24.
19. ^ "The Open Group Base Specifications Issue 7, Rationale, section 4.16 Seconds Since the Epoch". The OpenGroup. 2018. Archived from the original on 2017-11-15. Retrieved 2018-06-24.

Further reading

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• David Ewing Duncan (1999). The Calendar. Fourth Estate. pp. 331–332. ISBN 978-1-85702-979-6.
• Duncan Steel (2000). Marking Time: The Epic Quest to Invent the Perfect Calendar. John Wiley and Sons. pp. 149–151. ISBN 978-0-471-29827-4.
• Günther A. Wagner (1998). Age Determination of Young Rocks and Artifacts: Physical and Chemical Clocks in Quaternary Geology and Archeology. Springer. p. 48. ISBN 978-3-540-63436-2.

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