Hawaii National Park (Nature Notes)

HAWAII NATURE NOTES
THE PUBLICATION OF THE
NATURALIST DIVISION, HAWAII NATIONAL PARK
AND THE HAWAII NATURAL HISTORY ASSOCIATION

VOL. IV

MAY 1951

No. 2

KILAUEA, HOME OF PELE, THE FIRE GODDESS

DESCRIPTION. Kilauea also is a shield volcano, closely resembling Mauna Loa in its structure, built against the side of its larger neighbor. Small compared to Mauna Loa, Kilauea is no pygmy. Its summit stands some 20,000 feet above the surrounding ocean floor. Kilauea has been built largely by eruptions from two rift zones, extending eastward and southwestward from the summit caldera. The rifts are marked at the surface by many cinder and spatter cones, pit craters, and open fissures. The Chain of Craters road passes close to several of the pit craters on the east rift zone, and cuts through the edge of a small cinder cone revealing its internal structure. Noteworthy among the fissures on the southwest rift are the Great Crack, continuous for more than 10 miles, from which issued the 1823 lava flow of Kilauea; and the large fissures crossed by the road at the southwestern edge of the caldera.

The summit caldera ("crater") of Kilauea is 2-1/2 miles long and 2 miles wide, and its floor has an area of approximately 2,600 acres. At its north eastern edge, below the Volcano House, and at its western edge, below the Uwekahuna overlook, the wall of the caldera consists of a series of steplike fault blocks (Plate 14). Just north of Uwekahuna the boundary cliff is about 400 feet high. The entire floor of the caldera, except for a narrow peninsula projecting from the southeastern side, is made up of new lava flows erupted within the last century. (See Figure 4.) Near its southwestern edge the caldera floor is indented by the depression Halemaumau, the "Fire Pit," a collapsed crater about 750 feet deep. Halemaumau is the focus of Kilauea's eruptive activity and the traditional home of Pele, the Hawaiian goddess of volcanoes.

PLATE 15. Lava lake in Halemaumau, showing islands of semisolid epimagma in the fluid pyromagman, September 9, 1920. (T. A. Jaggar, HVO).

The pit craters along the rift zones are formed by collapse caused by removal of support. Some of the smaller ones may be formed by draining of large lava tubes underneath, with resulting collapse of the overlying rock material into the tube. The larger ones, such as Makaopuhi Crater at the end of Chain of Craters road, probably form above pluglike bodies of magma that work their way upward along the rift zone. Partial withdrawal of the magma causes the unsupported mass of rock above to sink in.

Many fault scarps can be seen on Kilaueae. The walls of the great caldera are themselves fault scarps left by the down-sinking of the floor. Along the rift zones elongate blocks of rock known as grabens have sunk down between two parallel faults, leaving infacing fault scarps at their edges. Along the southern coast Hilina Pali and its associated cliffs are scarps marking faults along which portions of the mountain have slid downward and outward toward the ocean.

Kilauea differs from Mauna Loa in two principal respects, both minor matters volcanologically. One is the greater amount of explosive debris in the vicinity of the caldera. The other is the lava lake activity that existed for many years in the caldera (Figure 6). The explosive debris around Kilauea caldera is of two types. One consists largely or entirely of fragments of glass—the quickly frozen spray of lava fountains. Deposits of this type of material are buff to yellow in color, and generally sandy in texture. They are well exposed in road cuts, fault scarps, and walls of cracks around the southern and southwestern edges of the caldera. In the same area a thin layer of pumice fragments lies on the ground surface. The pumice is the frozen froth of lava fountains that played in the caldera early in the 19th century.

FIGURE 4. Maps and cross-sections of Kilauea caldera in 1825 (after Malden) (A), and in 1949 (B). Note that the large central pit of 1825 has been entirely filled with new lava. The structure beneath the caldera is hypothetical. (From Stearns and Macdonald, 1946). (click on image for an enlargement in a new window)

The second type of explosive debris consists largely or entirely of stony fragments of older lavas, ranging in size from dust to blocks several feet across, broken up and thrown out by violent steam explosions such as those of 1924 described later. Two such periods of steam explosions have occurred during recent times, one about 1790 and the other in 1924. Debris thrown out in 1790 covers the ground surface in the vicinity of the Uwekahuna overlook. Material from the explosions in 1924 forms the surface around Halemaumau, and is abundant near the parking area. One block weighing about 8 tons was thrown 1,000 feet east of the present parking area and 3,000 feet from the center of Halemaumau. A still larger block, weighing about 14 tons, formerly lay near the rim of Halemaumau just north of the lookout platform, but fell back into the pit during a collapse of part of the rim.

A special type of explosive debris is the black sand that comprises the beaches near Kalapana and at some other localities. Where aa lava flows into the sea the contact of the hot lava with sea water causes steam explosions that throw up droplets and fragments of the hot lava. The droplets of still molten lava are quickly chilled to a black or dark brown glass. The debris from the explosions accumulates to form one or more small hills at the edge of the water. These hills are attacked by the ocean waves and soon eroded away. Of three such hills formed by the 1840 lava flow of Kilauea, one is already completely removed. The sand-size fragments, moved along the shore by the waves and currents, accumulate at favorable places to form beaches of black glass sand.

Table 3 lists the historic lava flows of Kilaueae. Comparison with Table 2 indicates that during the historic period activity has been concentrated in the caldera to a much greater degree than has that of Mauna Loa. The table ignores the long periods of constant lava lake activity at Kilauea, except when overflows of the lake produced noteworthy lava flows on the caldera floor. Undoubtedly many more of the latter occurred then are shown, especially during the early part of the historical period when records of the activity were poor.

TABLE 3—Eruptions of Kilauea¹


Year	Date of outbreak	Duration (days)	Altitude (feet)	Location	Approximate repose period since last eruption (months)²	Area (sq. miles)	²⁷Volume (cu. yards)

1750 (?)	----	----	1,700	E. rift	----	1.57	19,500,000
1790 (?)	----	----	1,100-750	E. rift	----	3.04	37,670,000
³l790	November (?)	----	----	Caldera	----	No lava flow	No lava flow
1823	Feb.-July	Short	1,700-250	SW. rift	----	⁴3.86	⁴15,000,000
1832	Jan. 14	Short	3,650	E. rim of caldera	----	(?)	(?)
1840	May 30	26	3,100-750	E. rift	----	⁴6.60	⁴281,000,000
1868	April 2	Short	3,350	Kilauea Iki	----	.07	(?)
1868	April 2 (?)	Short	2,550	SW. rift	----	.04	250,000
1877	May 4	1 (?)	3.500 (?)	Caldera wall	----	(?)	(?)
1877	May 21 (?)	----	3,450 (?)	Keanakakoi	----	.04	(?)
1884	Jan. 22⁵	1	-60 (?)	E. rift	----	(?)	(?)
1885	March	80 (?)	3,640 (?)	Caldera	14	(?)	(?)
1894	Mar. 21	6+	3,690	Caldera	108	(?)	(?)
1894	July 7	4 (?)	3,690	Caldera	3.5	(?)	(?)
1918	Feb. 23	14	3,700	Caldera	283	.04	250,000
1919	Feb. 7	⁶294	3,700	Caldera	11	1.60	34,500,000 (?)
1919	Dec. 21	221	3,000	SW. rift	1	5.00	62,000,000
1921	Mar. 18	7	3,700	Caldera	7.5	.77	8,800,000
1922	May 28	2	2,650-2,400	Makaopuhi and Napau	14	.04	(?)
1923	Aug. 25 (?)	1	3,000	E. rift	15	.20	100,000
⁷1924	May 10	17	----	Caldera	8	No lava	No lava
1924	July 19	11	2,365	Halemaumau	2.5	.02	320,000
1927	July 7	13	2,400	Halemaumau	35	.04	⁷3,160,000
1929	Feb. 20	2	2,500	Halemaumau	19	.06	1,920,000
1929	July 25	4	2,560	Halemaumau	5	.08	⁸3,600,000
1930	Nov. 19	19	2,600	Halemaumau	15.5	.09	¹⁰8,480,000
1931	Dec. 23	14	2,700	Halemaumau	12.5	.12	¹¹9,640,000
1934	Sept. 6	33	2,800	Halemaumau	44	.16	9,500,000
¹Many eruptions have occurred on the floor of the caldera, but only a few of the later ones are listed here, data being inadequate or totally lacking foe the earlier ones. On January 11, 1928. a small amount of lava was extruded on the floor of Halemaumau, but this is believed to have been squeezed out by the weight of a heavy landslide on the crust of the 1927 lava which was still fluid beneath (Jaggar, T. A., Volcano Letter 370, 1532). ²During the early historic period Kilauea caldera was observed only occasionally. and no definite record exists of the many caldera flows which are known to have occurred. ³Violently explosive. ⁴Area above sea level. The volume below sea level is unknown; but estimates give the following orders of magnitude: 1823—3,000,000 cubic yards; 1840—200,000,000 cubic yards. These are included in the volumes given in the table. ⁵Pacific Commercial Advertiser, Feb. 2, 1884. "A column of water, like a dome, shot several hundred feet up into the air, accompanied with clouds of smoke and steam." No further eruption was observed next day. ⁶Several separate flows, with short intervals without extrusion. ⁷Violent pheratic explosions, possibly accompanied by a submarine lava flow on the E. rift. ⁸Powers, H. A., Volcano Letter 242. 1929. ¹⁰Jaggar, T. A., Volcano Letter 311, 1930. ¹¹Jaggar, T. A.. Volcano Letter 366, 1931.

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24-Mar-2006