In order to understand the character of the rocks of Crater Lake National Park, it is necessary to have a general understanding of the major classes of rocks. According to their origin, all rocks can be placed in one of three groups: sedimentary, igneous, or metamorphic.

Most sedimentary rocks are composed of small particles of other primary rocks which have been transported and deposited in water. The common sedimentary rocks of this type are shale, sandstone, and conglomerate. Sedimentary rocks may also be formed from chemical precipitates of material that was dissolved in the water. Limestone is an example of this type of sedimentary rock.

Igneous rocks are formed by the solidification of molten rock, called magma. This magma originates far below the surface of the earth where the temperature is high enough to melt the rock.

Metamorphic rocks are formed when an existing rock is changed by heat, pressure, solutions, or a combination of these forces. For example, limestone is changed to marble, shale is changed to slate.

Because the rocks in Crater Lake National Park are igneous, a more detailed description of this type of rock is in order. In considering igneous rocks, a very important concept must be understood: the relationship between the rate of cooling of the magma and the resulting grain size. If the magma is cooled slowly, the constituent minerals have time to grow to large size; if the magma is cooled rapidly, more crystal nuclei form spontaneously and none can grow to large size. Extremely rapid cooling results in a non-crystalline rock, or glass called obsidian. The mineral crystals of an igneous rock may not be all of the same size. Because of some variation in the rate of cooling, the rock may consist of large crystals, called phenocrysts, embedded in a fine grained or glassy matrix called a groundmass. This rock, containing both large and small crystals, is called a porphyry.

There are two general classes of igneous rocks: intrusive or plutonic, and extrusive or volcanic. The intrusive rocks are those formed when the magma solidifies far below the surface of the earth. Because of the insulating properties of the overlying rock, the cooling is slow and the resulting rock is coarse grained. Granite is a common example of an intrusive igneous rock. Extrusive rocks are those formed when the magma, called lava in this case, is extruded to the surface of the earth. On the relatively cool surface the rock solidifies quite quickly and the resulting material is fine grained.

The shape of the topographic feature built up around the volcanic vent depends upon the physical characteristics of the rock that is extruded. If the extruded material consists of fragments, called pyroclastics, the resulting feature is called a pyroclastic cone. These cones are quite steep, but not very high because of the unconsolidated nature of the rocks. If the extruded material consists of lava flows, the resulting feature is called a shield volcano. The steepness of the slope depends upon the viscosity of the lava; the more viscous lavas pile up around the volcanic vent and produce a steeper slope than is produced by the more fluid lavas. A volcano composed of both pyroclastics and lava flows, roughly stratified, is called a stratovolcano.

There is a great variety of material ejected from volcanoes. The lava may flow from the crater in the summit or, more probably, from fissures in the sides. A volcano may erupt violently, throwing rock particles high into the air. This material may be fragments of solid rock torn from the sides of the vent or it may be clots of liquid rock or both. The size of these particles varies from masses weighing tons to fine dust. The largest are called blocks and the smaller particles are called, in order of decreasing size, cinders, ash, and dust. Volcanic bombs are rounded or twisted pieces of rock, formed from clots of molten rock hurled, spinning through the air.

Crater Lake exists in the caldera caused by the collapse of the upper portion of a volcano. The present cliffs above the lake reveal an excellent cross-section of this volcano which has been named Mt. Mazama. Alternate layers of various types of rocks indicate that this was a stratovolcano.

Most of the rock in the vicinity of Crater Lake is porphyritic andesite, a volcanic rock intermediate between the acidic rocks containing much silica and alumina, and the basic rocks containing the ferro- magnesian minerals. Andesite is typically light gray to dark gray in color, sometimes almost black. Less abundant than the andesite is a siliceous rock that occurs in two forms. Dacite is a hard, dense, glassy, gray rock. Its glassy appearance distinguishes it from andesite and it frequently has a definite flow structure. This dacite may be called obsidian, but the presence of phenocrysts renders it a glass porphyry instead of a true obsidian. The other siliceous rock is pumice, a light weight, porous rock formed from liquid rock with a great quantity of finely dispersed gas bubbles. Most of the pumice is so light that it will float on water. Another rock, basalt, is found only at lower elevations in the park. Basalt is a dense, hard rock which is dark colored because of the predominance of ferro-magnesian minerals. Its source in this area was a system of small volcanoes on the lower slopes of Mt. Mazama.

In Crater Lake National Park there are many excellent opportunities to observe the structure of the rocks. In the cliffs above the lake an excellent cross-section of this volcano is presented. From the lake, the rough layering in the walls is quite apparent. The strata consist of dense flows of andesite, layers of pyroclastics, pumice, and glacial till. There are also a few flows of dacite, prominent among which are Llao Rock and Redcloud Cliff. Dikes are other features to be observed from the lake. A dike is created upon the solidification of magma squeezed into a crack in an older formation. Devil's Backbone is the best example of a dike in this area.

The characteristics of a cinder cone and a block lava flow are best studied on Wizard Island. The main portion of the island is a cinder cone, simply an unconsolidated pile of cinders and ash. The base is a lava flow that is now almost completely covered by water. The west side of the island affords an excellent example of a block lava flow, whose angular fragments represent the solidified crust broken and pushed into its present form as viscous lava persisted in emerging from fissures in the sides of this volcano.

At lower elevations of the park, there are many spectacular gorges of which Llao's Hallway on Whitehorse Creek is particularly fascinating. It is an extremely narrow, deep gorge with steep walls that are vertical or undercut in many places. The rock is a very thick deposit of partially consolidated pumice.

A very common feature of these river gorges is en erosional structure often called "pinnacles." These structures occur in partially consolidated rock and are "fossil fumaroles," columns in the rock hardened by rising gases.

The visitor at Crater Lake is afforded an excellent opportunity to study the structure of a volcano. From the Garfield Peak trail one can observe both the interior of Mt. Mazama and the exterior including a considerable portion of the High Cascades. From the lake trail and from the motor launch the interior of this volcano may be studied in detail. On Wizard Island, the volcano that grew in the caldera quite recently, the visitor can study the well-preserved cinder cone and the block lava flow. Nature has indeed been generous in providing us with this deep caldera whose high walls, not obscured by talus or vegetation, reveal the history of a great fire mountain.