April 2015 lunar eclipse

April 2015 lunar eclipse

Total eclipse
Los Angeles, California, 12:00 UTC
Date	4 April 2015
Gamma	0.4460
Magnitude	1.0008
Saros cycle	132 (30 of 71)
Totality	4 minutes, 43 seconds
Partiality	209 minutes, 1 seconds
Penumbral	357 minutes, 31 seconds
Contacts (UTC) P1 09:01:27 U1 10:15:45 U2 11:57:54 Greatest 12:00:15 U3 12:02:37 U4 13:44:46 P4 14:58:58
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A total lunar eclipse took place on 4 April 2015. It is the former of two total lunar eclipses in 2015, and the third in a tetrad (four total lunar eclipses in series). Other eclipses in the tetrad are those of 15 April 2014, 8 October 2014, and 28 September 2015.

This is the 30th member of Lunar Saros 132, and the first total eclipse. The previous event was the March 1997 lunar eclipse, being slightly partial.

Duration

Totality lasted only 4 minutes and 43 seconds,^[1] making it the shortest lunar totality in almost five centuries since 17 October 1529 (which lasted 1 minute and 42 seconds). It was claimed by some that due to the oblateness of the Earth, it may have actually just been a partial eclipse.^[2] It was the sixth total lunar eclipse out of nine with totality under 5 minutes in a five millennium period between 2,000 BC and 3,000 AD. The eclipsed moon was 12.9% smaller in apparent diameter than the supermoon September 2015 lunar eclipse, measured as 29.66' and 33.47' in diameter from the center of the Earth. It occurred 3 days past apogee at 29.42'.

Visibility

The eclipse was visible across the Pacific, including all of Australia and New Zealand. It was visible near sunrise for North America, and after sunset for eastern Asia including India.

Visibility map

Background

Main article: Lunar eclipse

A lunar eclipse occurs when the Moon passes within Earth's umbra (shadow). As the eclipse begins, Earth's shadow first darkens the Moon slightly. Then, the shadow begins to "cover" part of the Moon, turning it a dark red-brown color (typically - the color can vary based on atmospheric conditions). The Moon appears to be reddish because of Rayleigh scattering (the same effect that causes sunsets to appear reddish) and the refraction of that light by Earth's atmosphere into its umbra.^[3]

The following simulation shows the approximate appearance of the Moon passing through Earth's shadow. The Moon's brightness is exaggerated within the umbral shadow. The southern portion of the Moon will be closest to the center of the shadow, making it darkest, and most red in appearance.

Gallery

Progression from Bali, Indonesia
Time-lapsed image from Taiwan	Sequence from Fox Observatory in Sunrise, Florida
Sequence from Melbourne, Florida	Progression from St. Louis, Missouri

• 
  Toronto, Canada, 9:54 UTC
• 
  Auckland, New Zealand, 9:54 UTC
• 
  Macon, Georgia, 10:54 UTC
• 
  Mexico City, Mexico, 10:59 UTC
• 
  Minneapolis, Minnesota, 11:09 UTC
• 
  Chicago, Illinois, 11:36 UTC
• 
  Melbourne, Australia, 11:46 UTC
• 
  Denver, Colorado, 11:50 UTC
• 
  Tai Po, Hong Kong, 12:01 UTC
• 
  Santa Clara County, California, 12:02 UTC
• 
  Las Vegas, Nevada, 12:03 UTC
• 
  Rio Rancho, New Mexico, 12:13 UTC
• 
  Bangkok, Thailand, 12:37 UTC
• 
  Hirosaki, Aomori, 12:56 UTC
• 
  Pune, India, 13:38 UTC

Timing

Local times of contacts

Time Zone adjustments from UTC		+8h	+11h	+13h	-10h	-8h	-7h	-6h	-5h	-4h
		AWST	AEDT	NZDT	HST	AKDT	PDT	MDT	CDT	EDT
Event		Evening April 4			Morning April 4
P1	Penumbral begins	N/A†	8:01 pm	10:01 pm	11:01 pm	1:01 am	2:01 am	3:01 am	4:01 am	5:01 am
U1	Partial begins	6:16 pm	9:16 pm	11:16 pm	12:16 am	2:16 am	3:16 am	4:16 am	5:16 am	6:16 am
U2	Total begins	7:58 pm	10:58 pm	12:58 am	1:58 am	3:58 am	4:58 am	5:58 am	6:58 am	Set
	Greatest eclipse	8:00 pm	11:00 pm	1:00 am	2:00 am	4:00 am	5:00 am	6:00 am	7:00 am	Set
U3	Total ends	8:03 pm	11:03 pm	1:03 am	2:03 am	4:03 am	5:03 am	6:03 am	Set	Set
U4	Partial ends	9:45 pm	12:45 am	2:45 am	3:45 am	5:45 am	Set	Set	Set	Set
P4	Penumbral ends	10:59 pm	1:59 am	3:59 am	3:59 am	5:59 am	Set	Set	Set	Set

† The Moon was not visible during this part of the eclipse in this time zone.

Contact points relative to the Earth's umbral and penumbral shadows, here with the Moon near its descending node.

v t e The timing of total lunar eclipses are determined by its contacts:[4] P1 (First contact): Beginning of the penumbral eclipse. Earth's penumbra touches the Moon's outer limb. U1 (Second contact): Beginning of the partial eclipse. Earth's umbra touches the Moon's outer limb. U2 (Third contact): Beginning of the total eclipse. The Moon's surface is entirely within Earth's umbra. Greatest eclipse: The peak stage of the total eclipse. The Moon is at its closest to the center of Earth's umbra. U3 (Fourth contact): End of the total eclipse. The Moon's outer limb exits Earth's umbra. U4 (Fifth contact): End of the partial eclipse. Earth's umbra leaves the Moon's surface. P4 (Sixth contact): End of the penumbral eclipse. Earth's penumbra no longer makes contact with the Moon.

Related eclipses

Eclipses of 2015

• A total solar eclipse on 20 March.
• A total lunar eclipse on 4 April.
• A partial solar eclipse on 13 September.
• A total lunar eclipse on 28 September.

Half-Saros cycle

A lunar eclipse will be preceded and followed by solar eclipses by 9 years and 5.5 days (a half saros).^[5] This lunar eclipse is related to two total solar eclipses of solar saros 139.

29 March 2006	8 April 2024

Lunar year series

The eclipse is the one of four lunar eclipses in a short-lived series at the ascending node of the Moon's orbit.

The lunar year series repeats after 12 lunations, or 354 days (shifting back about 10 days in sequential years). Because of the date shift, the Earth's shadow will be about 11 degrees west in sequential events.

Lunar eclipse series sets from 2013–2016
Ascending node					Descending node
Saros	Viewing date	Type	Gamma		Saros	Viewing date	Type	Gamma
112	2013 Apr 25	Partial	−1.0121		117	2013 Oct 18	Penumbral	1.1508
122	2014 Apr 15	Total	−0.3017		127	2014 Oct 08	Total	0.3827
132	2015 Apr 04	Total	0.4460		137	2015 Sep 28	Total	−0.3296
142	2016 Mar 23	Penumbral	1.1592		147	2016 Sep 16	Penumbral	−1.0549
Last set	2013 May 25				Last set	2012 Nov 28
Next set	2017 Feb 11				Next set	2016 Aug 18

Saros series

Lunar saros series 132, repeating every 18 years and 11 days, has a total of 71 lunar eclipse events including 44 umbral lunar eclipses (32 partial lunar eclipses and 12 total lunar eclipses).

Greatest	First
The greatest eclipse of the series will occur on 2123 Jun 9, lasting 106 minutes.[6]	Penumbral	Partial	Total	Central
	1492 May 12	1636 Aug 16	2015 Apr 4	2069 May 6
	Last
	Central	Total	Partial	Penumbral
	2177 Jul 11	2213 Aug 2	2429 Dec 11	2754 Jun 26

There are 11 series events between 1901 and 2100, grouped into threes (called an exeligmos), each column with approximately the same viewing longitude on earth.

1901–2100

1907 Jan 29		1925 Feb 8		1943 Feb 20
1961 Mar 2		1979 Mar 13		1997 Mar 24
2015 Apr 4		2033 Apr 14		2051 Apr 26
2069 May 6		2087 May 17

Tzolkinex

• Preceded: Lunar eclipse of February 20-21, 2008

• Followed: Lunar eclipse of May 15-16, 2022

See also

• List of lunar eclipses and List of 21st-century lunar eclipses

Notes

1. Espenak, Fred. "Total Lunar Eclipse of 2015 Apr 04" (PDF). NASA's GSFC.
2. "The Lunar Eclipse Wasn't Total After All?!". Sky & Telescope. 6 April 2015.
3. Fred Espenak and Jean Meeus. "Visual Appearance of Lunar Eclipses". NASA. Retrieved 13 April 2014.
4. Clarke, Kevin. "On the nature of eclipses". Inconstant Moon. Cyclopedia Selenica. Retrieved 19 December 2010.
5. Mathematical Astronomy Morsels, Jean Meeus, p.110, Chapter 18, The half-saros
6. Listing of Eclipses of series 132

External links

• 2015 Apr 04 chart: Eclipse Predictions by Fred Espenak, NASA/GSFC
• Hermit Eclipse: Total Lunar Eclipse: April 4, 2015
• Mattastro.com Total Lunar Eclipse: April 4, 2015
• Full Moon in Earth's Shadow APOD 2015 April 8