Pyroxene

Definition

Pyroxene refers to a group of important rock-forming inosilicate minerals found in many igneous and metamorphic rocks. These minerals are characterized by their crystal structure, which consists of chains of silicate tetrahedra. Pyroxenes are commonly found in basalt and other volcanic rocks and are significant in geological studies due to their role in the Earth's crust.

Synonyms

• Silicate mineral
• Inosilicate
• Rock-forming mineral

Antonyms

• Non-silicate mineral
• Organic compound

Examples

1. The geologist examined the pyroxene in the rock sample.
2. During the field study, we identified various types of pyroxene.
3. The pyroxene crystals were found embedded in the granite.
4. Analysis of the pyroxene composition provided insights into the rock's formation.
5. The pyroxene content in basalt is typically high.
6. Researchers studied how pyroxene affects magma viscosity.
7. The pyroxene minerals were distinguished by their unique colors.
8. Pyroxene can form under high-pressure conditions in the Earth’s mantle.
9. The presence of pyroxene indicates a specific geological environment.
10. Different varieties of pyroxene can be found in metamorphic rocks.
11. The scientist used a microscope to analyze the pyroxene structure.
12. Pyroxene may occur in both igneous and metamorphic rocks.
13. The pyroxene group includes minerals like augite and diopside.
14. In the lab, we learned to identify pyroxene through their cleavage patterns.
15. The pyroxene grains were visible under the thin section of the rock.
16. We discussed the significance of pyroxene in volcanic activity.
17. The student wrote an essay on the role of pyroxene in geology.
18. Pyroxene can be an indicator of the cooling history of magma.
19. The pyroxene found in the sample had a distinctive luster.
20. We compared the pyroxene content across different rock types.
21. The team analyzed the pyroxene to understand the mineralogy of the area.
22. Pyroxene minerals can vary significantly in composition.
23. The researcher noted the presence of pyroxene in the sedimentary layer.
24. The pyroxene crystals can reveal information about the volcanic eruption.
25. A high concentration of pyroxene can indicate a basaltic origin.
26. The geology class examined thin sections containing pyroxene.
27. The team collected samples to study the pyroxene distribution.
28. The mineralogy report highlighted the importance of pyroxene.
29. The pyroxene in this rock type can affect its physical properties.
30. We identified the pyroxene under ultraviolet light.
31. The mineralogy of the area is rich with pyroxene varieties.
32. Students learned about the formation of pyroxene in igneous rocks.
33. The pyroxene group includes clinopyroxene and orthopyroxene.
34. The researchers hypothesized that the pyroxene originated from deep within the Earth.
35. The pyroxene minerals can be used to date geological events.
36. Rock samples often contain various forms of pyroxene.
37. The pyroxene crystals were larger than expected.
38. The pyroxene was examined for its potential industrial applications.
39. The pyroxene mineralogy is critical for understanding plate tectonics.
40. During the seminar, we explored different properties of pyroxene.
41. The presence of pyroxene can influence a rock's melting point.
42. Detailed studies of pyroxene can provide insights into Earth's history.
43. The pyroxene in the sample was identified as enstatite.
44. We discussed how pyroxene interacts with other minerals.
45. The pyroxene structure allows for various substitutions in its composition.
46. The lab experiment focused on the thermal stability of pyroxene.
47. Pyroxene minerals can be indicators of tectonic activity.
48. The pyroxene found in meteorites can shed light on extraterrestrial processes.
49. The pyroxene crystals were analyzed for their optical properties.
50. The geological survey reported a high abundance of pyroxene in the region.
51. The pyroxene group includes minerals that are crucial for understanding igneous processes.
52. The pyroxene composition can be altered through metamorphism.
53. The field trip helped students recognize the characteristics of pyroxene.
54. We studied the relationship between pyroxene and other silicate minerals.
55. The pyroxene mineral group is a significant part of the Earth’s crust.
56. The identification of pyroxene was a key finding in our research.
57. The pyroxene content can affect the color of the rock.
58. In the lab, we prepared thin sections to analyze pyroxene.
59. The pyroxene found in the sample had unique crystallographic features.
60. The research team presented their findings on the role of pyroxene in rock formation.
61. The pyroxene minerals can provide evidence of past volcanic activity.
62. The study of pyroxene is essential for understanding mineral formation.
63. The pyroxene structure was carefully documented in the research paper.
64. We discussed the implications of pyroxene in Earth's mantle dynamics.
65. The pyroxene found in the region had distinct optical properties.
66. The pyroxene mineral was identified through X-ray diffraction techniques.
67. Researchers debated the classification of the pyroxene samples.
68. The pyroxene in the specimens was analyzed for its chemical composition.
69. The presence of pyroxene can indicate previous volcanic activity.
70. The pyroxene crystals were examined for their growth patterns.
71. The geology class focused on the significance of pyroxene in metamorphic rocks.
72. The pyroxene content in the rock can reveal its cooling history.
73. During the analysis, we found various pyroxene minerals.
74. The pyroxene in the sample was found to be rich in magnesium.
75. The pyroxene composition can be affected by temperature and pressure.
76. The study of pyroxene is vital for understanding geological processes.
77. The pyroxene group includes minerals that can form in a variety of settings.
78. The pyroxene crystals were documented for their size and shape.
79. We learned about the role of pyroxene in rock classification.
80. The pyroxene in the rock sample was analyzed using scanning electron microscopy.
81. The pyroxene structure can influence the physical properties of rocks.
82. The pyroxene found in the area is of significant interest to geologists.
83. The lab results indicated a high presence of pyroxene.
84. The pyroxene was carefully extracted for further analysis.
85. We discussed the environmental implications of pyroxene mining.
86. The pyroxene samples were sent for further chemical analysis.
87. The pyroxene minerals can affect the texture of the rock.
88. The research focused on the relationship between pyroxene and plate tectonics.
89. The pyroxene in the sample was identified as a key mineral.
90. The geology report highlighted the diversity of pyroxene in the region.
91. The pyroxene was found to contain significant amounts of iron.
92. The pyroxene mineral group is known for its complex crystal structures.
93. The pyroxene content can vary between different rock formations.
94. The pyroxene found in this region is of particular interest due to its rarity.
95. The study of pyroxene can help in understanding volcanic processes.
96. The pyroxene minerals were compared for their physical and chemical properties.
97. The presence of pyroxene is often associated with specific geological conditions.
98. The report found that pyroxene varied significantly throughout the region.
99. The pyroxene structure can exhibit different cleavage patterns.
100. The pyroxene in the sample was analyzed for its potential uses in industry.