USGS: Geological Survey Professional Paper 446: Geology of the Guadalupe Mountains, New Mexico (Economic geology)

Geological Survey Professional Paper 446

Geology of the Guadalupe Mountains, New Mexico

ECONOMIC GEOLOGY

OIL AND GAS

PREVIOUS EXPLORATION

Up to June 30, 1961, 81 holes had been drilled in search of oil and gas within the report area; all but 17 of these holes are in the Delaware basin (table 2). Eight of the Delaware basin wells yielded oil, and four yielded gas of commercial value. Four of the oil wells were still producing early in 1960.

TABLE 2.—Oil and gas test wells drilled in report area before June 30, 1961
[Abd., abandoned, dry hole; OW, oil well; AOW, abandoned oil well; GW, gas well]


Sec.	Township (S)	Range (E)	Location	Status	Well	Altitude (feet)	Total depth (feet)	Year completed

16	21	22	C, SW, SE	Abd.	Magnolia State "W" 1	4,464	11,312	1948
22	21	22	C, NE, NW	Abd.	Union Federal 1—22	4,325	5,579	1960
23	21	22	C, NW, NW	Abd.	Magnolia Crosby 1—X	4,250	3,043	1949
29	21	22	C, SE, NE	Abd.	Magnolia Golden 1	4,478	3,970	1949
1	22	21	C, SE, SE	Abd.	Continental East Texas Hill Unit 1	4,573	10,596	1954
5	22	21	SW, SE, SE	Abd.	Continental-Standard of Texas Bass 1	5,511	5,889	1952
28	22	21	NW, SW, NE	Abd.	Sinclair Federal-Eddy 1—193	5,197	5,000	1961
32	22	21	C, NE, NE	Abd.	Sinclair Federal-Eddy 1—195	5,360	4,000	1960
32	22	22	C, NE, NE	Abd.	Texas Crude Oil State of New Mexico "A" 1—32	4,564	5,300	1961
6	23	22	SW, NW, NW	Abd.	Texas Crude Oil Federal Huapache 1—6	5,124	3,720	1961
23	23	22	SE, SE, NW	Abd.	Humble Huapache Unit 2	4,455	12,582	1957
35	23	22	NW, SW, NW	Abd.	Humble Huapache Unit 1	4,425	12,631	1955
14	24	22	C, SW, SW	Abd.	Humble Huapache Unit 4—1	5,502	7,950	1960
17	24	22	C, NW, NW	Abd.	Union White 1	5,709	6,737	1955
22	24	22	C, SE, NW	Abd.	Humble Huapache Unit 3	5,625	8,670	1959
25	24	22	C, NW, NE	Abd.	British-American Huapache Unit 7	5,505	3,620	1961
4	24	26	C, SW, NE	Abd.	Bauerdorf Schrup 1	3,405	1,970	1951
14	24	22	SE, SW, NE	Abd.	Humble Huapache Unit 5	5,352	3,505	1960
10	24	26	SE, NE, SE	Abd.	Street Investment Co. 1 Bradley	3,305	2,061	1949
11	24	26	SW, SW, NE	Abd.	Jos. I. O'Neill, Jr. Federal "D" 1	3,291	2,014	1958
11	24	26	SE, NE, SW	Abd.	Shappell Bradley 9	3,281	2,026	1949
11	24	26	SE, NW, SE	OW	Shappell Bradley 8	3,271	1,975	1949
11	24	26	SW, NE, SE	Abd.	Shappell Bradley 6	3,275	2,000	1948
11	24	26	NE, SW, SE	Abd.	Shappell Bradley 7	3,271	2,000	1949
11	24	26	NW, SE, SE	OW	Shappell Bradley 5	3,266	1,971	1948
11	24	26	SE, SE, SE	OW	Shappell Bradley 2	3,260	1,968	1947
12	24	26	SW, SW, NW	Abd.	R. A. T. Wright, Wright 1	3,277	2,024	1954
13	24	26	NW, NW, NW	OW	Shappell Bradley 1	3,260	1,969	1947
13	24	26	C, NW, NW	AOW	Collins Weiler 1	3,245	1,969	1937
13	24	26	NW, NE, NW	Abd.	Shappell Bradley 4	3,260	2,015	1947
14	24	26	SE, SE, NW	Abd.	Bradley Bradley 1	3,275	2,114	1950
14	24	26	NE, NE, NE	AOW	Grisham Chaytor 1	3,255	2,320	1937
14	24	26	SE, NE, NE	Abd.	Shappell Bradley 3	3,253	1,978	1947
17	24	26	NE, NE, NE	Abd.	E.P. Campbell Lee 1	3,349	1,920	1958
20	24	26	SW, SW, NE	Abd.	Gulf Federal Estill 2—AD	3,396	11,420	1960
23	24	26	C, NE, NW	Abd.	Crawford Crawford 2	3,270	2,000	1952
23	24	26	NE, NE, NE	Abd.	Hargrave Hargrave 1	3,266	2,032	1953
23	24	26	NE, NE, SE	Abd.	Hargrave Dean-Smith 1	3,260	2,005	1951
24	24	26	NW, NW, NW	AOW	York & Harper Bradley 1	3,263	1,986	1951
24	24	26	NW, NW, NW	AOW	Leda Oil Elliot-Hargrave 1	3,260	1,978	1953
24	24	26	NW, NW, SW	Abd.	Moran Crawford & Smith 1	3,241	2,005	1938
26	24	26	C, NW, SE	GW	Union Crawford 1—26	3,261	11,522	1957
27	24	26	C, NW, SE	GW	Union Crawford 2—27	3,315	11,360	1960
28	24	26	NE, SE, SW	Abd.	E.P. Campbell Estill 1	3,341	2,125	1958
29	24	26	C, NE, NE	GW	Gulf Estill 1—AD	3,411	12,212	1960
29	24	26	SE, SW, NW	Abd.	Martin & Lycette Pardue & Guitar 1	3,442	1,875	1938
30	25	25	C, SW, NE	Abd.	Gulf Federal Kelly 1—A	3,681	11,296	1961
30	25	25	C, SW, SW	Abd.	John M. Kelly Federal-Esther 1	3,705	1,432	1958
34	25	25	C, NW, NW	Abd.	Carper Gates 1	3,650	2,004	1949
9	25	26	C, SW, SW	Abd.	Cree Drg. Co. Union-Parke 1	3,359	2,035	1958
10	25	26	SE, SE, SE	Abd.	Brock Jennings 1	3,379	2,141	1951
10	25	26	SE, SE, SE	Abd.	Roach & Shepard Gates 1	3,372	2,107	1948
11	25	26	C, NE, NE	Abd.	Cree Drg. Co. Gulf 1	3,365	2,215	1958
11	25	26	C, SW, NE	Abd.	Gulf Jennings 1—E	3,350	2,167	1959
26	25	26	C, SW, SW	Abd.	Cree Oil Co. Ashland 1	3,313	2,110	1958
1	26	24	NW, NW, NW	Abd.	G. C. Weaver Smith 3	3,730	889	1956
8	26	24	NE, NW, NE	Abd.	John A. Yates Matlock 1	3,832	3,500	1956
9	26	24	C, NW, NW	Abd.	Randel Thurman 1	3,806	595	1952
9	26	24	C, NE, SE	Abd.	D. S. Harroun Mayes 1	3,737	612	1957
10	26	24	NW, SW, NW	Abd.	Smith State-Mayes 1	3,725	600	1950
10	26	24	C, SE, NE	Abd.	D. S. Harroun Leeman 1	3,715	640	1957
10	26	24	NW, NE, SW	Abd.	Smith State-Leeman 1	3,723	675	1950
12	26	24	C, SE, NE	GW	Superior Federal 1—134	3,878	10,237	1960
14	26	24	N, SW, NW	Abd.	G. C. Weaver Smith 1	3,870	2,513	1955
15	26	24	C, SW, NW	Abd.	D. S. Harroun Mayes 1	3,774	767	1958
19	26	24	C, NW, SE	Abd.	D. S. Harroun Leeman 2	3,715	618	1958
22	26	24	NW, NW, NW	Abd.	G. C. Weaver Smith 2	3,765	707	1955
22	26	24	NW, NW, NE	Abd.	G. C. Weaver Smith 4	3,813	788	1956
22	26	24	NE, NW, NE	Abd.	G. C. Weaver Smith 5	3,830	788	1956
22	26	24	NE, NE, SE	Abd.	G. C. Weaver Jenson 1	3,955	956	1956
23	26	24	SE, NW, NW	Abd.	G. C. Weaver Smith 1—23	3,869	902	1955
1	26	25	SE, SE, NE	Abd.	W. E. Doolin Milner 1	3,490	1,870	1957
3	26	25	SW, SW, SW	Abd.	W. E. Doolin Erickson 1	3,686	1,820	1957
26	26	25	NW, NW, NW	Abd.	W. E. Doolin McKean 1	3,602	1,488	1957
2	26	26	C, SE, SE	Abd.	John M. Kelly State "EP" 1	3,287	2,057	1958
5	26	26	NE, NE, SE	Abd.	W. E. Doolin Hodges 1	3,482	1,935	1957
7	26	26	C, SE, SW	Abd.	McBride Randel 1	3,541	2,702	1951
17	26	26	SE, SE, NW	Abd.	W. E. Doolin Randel 1—X	3,472	1,832	1957
19	26	26	SW, SW, SW	Abd.	W. E. Doolin Price 1	3,454	1,620	1957
28	26	26	NE, NE, SE	Abd.	W. E. Doolin Watkins 1	3,432	1,870	1957

All the oil wells are in the Black River field and produce 42° gravity API oil (Stipp and others, 1956, p. 73) from fine-grained sandstone and siltstone just beneath the Lamar Limestone Member of the Bell Canyon Formation. This field is apparently on a small anticlinal nose or structural terrace. Production has never exceeded a few barrels per day per well.

The first gas well was the Union Oil Co. of California Crawford 1—26 (sec. 26, T. 24 S., R. 26 E.), about 2 miles south of the Black River field. This well had an initial production capacity of 62,000 Mcf (thousand cubic feet.) of natural gas per day from a depth of 11,060 to 11,074 feet in Lower Pennsylvanian rocks. The other gas wells are the Gulf Oil Corp. Estill 1—AD (sec. 29, T. 24 S., R 26 E.), the Union Oil Co. of California Crawford 2—27 (sec 27, T. 24 S., R. 26 E.), and the Superior Oil Co. Federal 1—134 (sec. 12, T. 26 S., R. 24 E.). These wells, which also produce from Pennsylvanian rocks, had initial production capacities of 46,000, 7,200, and 347 Mcf per day, respectively.

Of the remaining 52 test wells which have been drilled in the Delaware-basin part of the report area, 47 were drilled no deeper than a few feet below the Lamar Limestone Member of the Bell Canyon Formation, and 3 were apparently drilled into the underlying Cherry Canyon Formation. Thus, only 6 wells in this 255-square-mile area have penetrated pre-Permian rocks, and only 9 have been drilled deeper than the shallowest potential producing zone.

In the shelf area outside the Delaware basin, 17 test wells have been drilled in about 730 square miles of area. All of them were dry holes. Three of the holes were drilled to Precambrian rocks, and eight were drilled into pre-Devonian rocks. The greater concentration of exploratory wells is in the Delaware basin; however, the average depth of the wells in the shelf area is about 4,000 feet greater than the average for wells drilled in the basin where the sedimentary rocks are thicker.

FUTURE POSSIBILITIES

On the basis of results of previous drilling in areas to the east, northeast, and southeast, it appears that the best potential production zones in the Delaware basin are in the Bone Spring Limestone, Pennsylvanian rocks, limestone of possible Devonian age above the Fusselman Dolomite, and the El Paso Formation. The best potential structural conditions for accumulation of oil and gas might be found on the southeast projection of the trend of the Huapache monocline (pl. 1) where buried structure similar to the Huapache thrust zone might be present (p. 42). To date (1961), most of the Delaware-basin oil fields produce from near the top of the Bell Canyon Formation. More such fields may be found.

Exploration for oil and gas in the Guadalupe Mountains area has been disappointing. The greatest potential probably lies in the Lower Permian and Pennsylvanian rocks of the Seven Rivers Embayment, adjacent to the Huapache monocline (pl. 1); but as in the Delaware basin, pre-Pennsylvanian rocks offer possibilities throughout the shelf area.

GYPSUM

Vast deposits of relatively pure fine-grained gypsum in the Castile Formation underlie an area of more than 100 square miles in the southeastern part of the area. These deposits are at or near the surface and are as much as several hundred feet thick. Probably enough gypsum is present to supply the total world demand for centuries, and much of it is of sufficient purity for industrial purposes. However, the price of gypsum has been so low in relation to transportation costs that up to June 1960 no important attempt had been made to exploit the deposits.

Although most of the vast quantities of gypsum in the area are fine grained, some selenite of fair quality is present; but none of optical quality has yet been found. The best potential area for prospecting is in the Yeso Hills, where selenite occurs along the east-northeast-trending linear features indicated on the geologic map (pl. 1). At least one prospect hole has been dug in this area and selenite is abundant around it.

BUILDING STONE

No high-quality building stone is present in the area, but flaggy dolomite from the Tansill Formation has found local use, notably for the construction of buildings at Carlsbad Caverns for the U.S. National Park Service. Other rocks have been used by local residents for houses and stone walls.

GRAVEL

Limestone gravel deposits have been quarried at several places along U.S. Highway 62 for use as road metal. In most places the gravel requires screening, but the supply meets the limited demand.

SODIUM SULFATE

Concentrated brines rich in sodium and magnesium sulfate are present locally in gypsum immediately overlying unaltered anhydrite in the Castile Formation. In 1906 brine was discovered at a depth of 160 feet in a well drilled for water in sec. 30, T. 25 S., R. 27 E., about 1 mile east of the mapped area. In 1934 brine from a depth of 170 feet from another water test hole drilled in sec. 29, T. 24 S., R. 26 E., was analyzed and found to contain abundant sodium sulfate (Lang, 1941, p. 152). Since then, about 65 test wells have been drilled in the mapped area in search for brine in the Castile Formation. Of these test holes, in at least 32 brine was found at depths ranging from 67 to 165 feet. These wells are in sec. 36, T. 25 S., R. 25 E.; secs. 14, 16, 22, 23, 25, 26, 27, 30, 32, 35, and 36, T. 25 S., R. 26 E.; and secs. 2 and 3, T. 26 S., R. 26 E. Until 1957, brine was produced commercially by the Ozark-Mahoning Co. from a well near Paxton water well in Cottonwood Draw. The brine was transported for the purpose of separation of the sodium sulfate more than 100 miles by truck to Monahans, Tex. The operation was stopped for an indefinite period in 1957 because of pumping and transportation costs (Robert S. Fulton, written communication, August 1958). Production figures are not known.

Chemical analyses of brines from four wells, as reprinted from Lang (1941, p. 154), are listed in table 3.

TABLE 3.—Chemical analyses of brines from four wells Eddy County, N. Mex.
[Laboratory of the U.S. Geological Survey, Midwest, Wyo. 1, Forehand 2, sec. 25, T. 25 S., R. 26 E.; 2, Mullen 1, sec. 30, T. 25 S., R. 26 E.; 3, Gates-Pardue Guitar 1, sec. 26, T. 25 S., R. 26 E.; 4, D. P. Welch 2, sec. 8, T.26 S., R. 27 E.]

	Grams per liter
	1	2	3	4
Magnesium (Mg)	41.3	46.2	23.5	39.6
Sodium (Na)¹	43.1	59.5	61.1	32.3
Potassium (K)	16.6	1.8	4.6	1.2
Sulfate (SO₄)	236.7	245.5	304.1	187.2
Chloride (Cl)	24.8	39.7	24.4	25.4
Carbonate (CO₃)	.3	—	.7	—
Bicarbonate (HCO₃)	1.0	4.1	1.8	1.7
Borate (B₄O₇)	2.9	10.3	7.4	4.0
Total solids	366.7	407.5	458.0	291.4
Specific gravity	1.290	1.326	1.363	1.236

¹Sodium calculated; other constituents determined.

Lang (1941, p. 156-157) stated that meteoric waters percolating through porous weathered gypsum in the vadose zone in the Castile Formation could acquire all the elements that make up the sodium sulfate brines. He further stated that normal ground-water circulation would tend to remove the brine, but that some brines could become trapped in "inverted closures or pockets" on top of massive unaltered anhydrite of the Castile. The presence of significant amounts of magnesium, potassium, and borate in the brines (table 3) suggests that they are residual brines from solution of the Salado Formation which is now present in the area only as residuum at the top of the Castile Formation. Magnesium, potassium, and borate are very rare in the Castile Formation, but potassium and magnesium minerals, at least, are present in some abundance in the Salado Formation east of the Pecos River. Further more, all the brines known in the area occur in or just below the residuum of the Salado.

GROUND WATER

The ground-water resources of the Eddy County part of the Guadalupe Mountains area have been described by Hendrickson and Jones (1952), and Hale (1955) has reported on ground-water conditions in the upper part of Black River valley. The following discussion is in part a summary of those reports but includes minor additional comments.

The availability and quality of ground water in the Guadalupe Mountains area vary markedly from place to place, depending on the character and structure of the rocks. For purposes of discussion, the area may be divided into six areas of ground-water availability (fig. 29).

FIGURE 29.—Areas of ground-water availability discussed in text.

BROKEOFF MOUNTAINS-DOG CANYON AREA

No springs or perennial surface streams occur in the Brokeoff Mountains-Dog Canyon area, and attempts to locate a satisfactory ground-water reservoir there have failed. Nearly all the domestic and stock water used in the area is rainwater stored in cisterns and earth tanks, but a minor amount is trucked in from adjacent areas. The scarcity of available ground water probably can be attributed to the great concentration of high-angle fault planes and joints that provide avenues of drainage and to the scarcity of shallow impermeable beds that might support perched water reservoirs. Any drilling for water here will have a better chance for success if the well is located on the basis of careful study of structural and stratigraphic conditions. The ideal location would be a fault-free syncline underlain by shallow impermeable beds. However, little of the area is free of faults, and impermeable beds are thin and scarce north of Martine Ridge. The part of Upper Dog Canyon east of Martine Ridge may approach ideal conditions.

NORTHERN GUADALUPE MOUNTAINS

The northern Guadalupe Mountains are also without springs or perennial streams, but several drill holes have tapped water near the contact of the San Andres Limestone and the Yeso Formation at depths between 600 and 1,300 feet. It is unlikely that water in sufficient quantity for watering stock will ever be found at shallow depth in this part of the area. Small quantities of water for domestic use may be present in the alluvium of some of the larger canyons.

SEVEN RIVERS EMBAYMENT

No permanent surface streams or springs are in the Seven Rivers Embayment. Potable ground water generally is present in quantities sufficient for domestic and stock-watering uses, but its depth is difficult to predict. Wells drilled near the west edge of the embayment, on or near the San Andres Limestone outcrop, generally do not strike water at depths shallower than 600 to 900 feet, but locally the arroyo gravels may contain small quantities of water at shallow depth. Toward the east, water is obtained from the Grayburg Formation at depths of 75 to 300 feet.

GUADALUPE RIDGE

The occurrence of ground water in the Guadalupe Ridge area is erratic, as it is dependent on variable local structural and stratigraphic conditions. Where structural conditions are favorable, water in sufficient quantity and of suitable quality for stock and domestic uses is often present in dolomite and limestone beds that overlie relatively impervious clastic beds in the San Andres Limestone, sandstone tongue of the Cherry Canyon Formation, the Artesia Group, and the Capitan Limestone. Where topographic conditions permit, water from these perched aquifers comes to the surface in nearly 50 seeps and springs, 2 of which maintain short stretches of surface streams. Sitting Bull Spring (sec. 9, T. 24 S., R. 22 E.), the larger of these 2 springs, emerges from a dolomite tongue of the San Andres Limestone which overlies relatively impervious clastic beds of the sandstone tongue of the Cherry Canyon Formation. The flow from the spring irrigates a small apple orchard near the mouth of Sitting Bull Canyon and furnishes drinking water to the U.S. Forest Service Recreation area (fig. 23).

The stream gravels of Dark Canyon, and possibly other canyons, locally contain important quantities of shallow ground water in the Guadalupe Ridge area. Where the limestone bedrock rises near the surface, springs emerge from the overlying alluvium in Dark Canyon in sec. 25, T. 24 S., R. 22 E., and sec. 31, T. 24 S., R. 23 E. Water from these springs is used to irrigate fields near the X-Bar Ranch headquarters.

Drilling for water in the Guadalupe Ridge area has produced numerous dry holes. Where water has been found, its depth ranges from a few feet to several hundred feet. Probably the percentage of successful water wells in the area could be increased greatly if drilling were done in synclinal areas which geologic relations indicate are underlain by relatively impervious siltstone beds that could support perched water.

MESCAL WASH AND BLACK RIVER VALLEY AREA

The Mescal Wash and Black River valley area is underlain by more available ground water than the mountain areas. This ground water comes to the surface in nearly a dozen springs and seeps, the most notable being Blue, Rattlesnake, and Geyser Springs, each of which flows generally in excess of 1,000 gpm (gallons per minute). Blue Spring, the largest spring, has an average flow in excess of 5,000 gpm and furnishes irrigation water to a sizable farming development near Black River Village. The extensive gravel deposits of Mescal Wash, south of Rattlesnake Canyon and west of Black River, probably comprise the most dependable reservoirs of potable ground water in the entire report area. Here, large volumes of water are pumped for irrigation from depths of 100 to 300 feet. North and east of Rattlesnake Canyon and along Black River itself, where the gravel deposits are thin to absent, the occurrence and quality of ground water is much less predictable. In general, the waters here contain more sulfate than those in Mescal Wash and are nearly unpotable. A detailed analysis of the ground-water conditions in the Mescal Wash and Black River valley area was made by Hale (1955).

YESO HILLS AND GYPSUM PLAIN

In the Gypsum Plain, small amounts of highly gypsiferous water, probably from fractures in the Castile Formation, reach the surface at Cottonwood Spring (sec. 35, T. 25 S., R. 25 E.), Ben Slaughter Spring (sec. 7, T. 26 S., R. 26 E.), and Jumping Spring (sec. 17, T. 26 S., R. 26 E.). The surface drainage on the Castile Formation is apparently controlled by an eastward-trending fracture system (Hayes, 1957; Olive, 1957, p. 356-357), and wells drilled here in valley bottoms often tap water at shallow depth. Water from the Castile Formation or from gypsiferous alluvium derived from the Castile Formation generally is suitable for livestock, but a sulfate content of as much as 1,500 to 1,800 ppm (parts per million) is not unusual (Hendrickson and Jones, 1952, p. 163-164). The only ground water known near the east edge of the area is the heavy sulfate brine discussed on pages 56-57.

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Last Updated: 13-Feb-2008