Rock varieties of Hawai'i
Contrary to what you may have heard, it's not all basalt. Even the basalt is astonishingly varied: the extrusive rock of a thousand faces... Here I'll share some pictures I took of rocks in Hawai'i:
There's pahoehoe:
...and there's a'a:
Here's a pahoehoe flow oozing over my boot (just kidding; it was cold when I did this):
Pahoehoe lobes can drain out, leaving only the outer skin as rock, but with a hollow center. These are lava tubes (nickel for scale):
Another one (nickel for scale):
Cool texture on the inside of this lava tube (nickel for scale):
...and zooming in a bit closer (it looks like wrinkled cellophane!):
A stack of cross-sectioned pahoehoe flows, showing their tubular (totally tubular, dude) shape:
Some Hawai'i basalt is massive, like this cobble...
...or like this cobble of hawaiite, a dense form of basalt found atop Mauna Kea (where it apparently erupted beneath Pleistocene ice caps):
But the majority of Hawai'i's basalts are vesicular, meaning they contain "Swiss Cheese" type holes that result from gas bubbles. When the lava erupts, it experiences less pressure at the Earth's surface than it was subjected to at depth. As a result, many gases (steam, CO2, sulfur dioxide, chlorine, argon, others) exsolve from the lava solution and make bubbles. If these bubbles don't get a chance to pop before the lava sets up into igneous rock, then they are preserved as vesicles. Sometimes the vesicles are small:
...and sometimes they are big:
Sometimes, they are really big. Here's one I could fit my entire Nalgene water bottle into:
When vesicles later get filled in with mineral deposits, we call them amygdules. Here's some vesicles that have gotten a light coat of a white mineral on their interiors: the first step to converting a vesicle into an amygdule:
Some of the vesicles show strain (almost certainly due to late-stage flow in the increasingly-viscous lava, getting stretched out like air bubbles in pouring honey). Surface tension on the bubble wants to make it spherical, and the lower the lava's viscosity, the easier it will be to attain that perfect spherical shape, minimizing the surface-area-to-volume ratio. So when we find them in cigar-shapes or pancake-shapes instead, that's a clue that they've been deformed. Deformed not by tectonic forces (ductile flow at depth in an orogen), but ductile flow as a result of their formation, in a sluggishly oozing blob of lava:
Another example of stretched-out vesicles:
A lonely vesicle in an otherwise massive basalt:
Not sure what's going on here, but it looks cool (popped vesicles in sticky lava?):
Another thing you see a lot of in these Hawai'ian basalts are phenocrysts of certain minerals. Here, for instance, is a cobble showing nice olivine phenocrysts:
...and another:
Here's one I showed you last week when we discussed Green Sands Beach:
Here's an outcrop which shows phenocrysts of plagioclase feldspar instead:
And a river cobble (also vesicular) bearing a healthy population of feldspar phenocrysts:
Holy feldspar, Batman! This rock has a huge proportion of feldspars (you'll note that it's still vesicular, though: in spite of the overwhelming volume of macroscopic crystals, this is still an extrusive rock):
Here's something else caught up in a finer grained (and yes, vesicular) basaltic matrix: another piece of basalt!
This is a xenolith of slightly-older basalt showing flow banding in its own trains of vesicles, that after solidification got broken off and included in younger flows of basalt. I'll post some additional xenolith photos later this week.
It's not all basalt, though. Here's a breccia made of basaltic cobbles (penny for scale):
And a closer shot of the same outcrop (penny for scale):
Finally, a rock I was surprised to see: an intermediate-composition extrusive igneous rock called benmoreite (nickel for scale, and note the rock hammer impact marks):
Benmoreite is way more felsic that anything else on the island. According to my volcanic advisor Jess, it's the result of late-stage partial melting of basaltic source rocks in the island's oldest volcano, Kohala. In other words, it's a distillation of basalt: concentrating the most felsic components in this decidedly-lighter-complected rock (nickel for scale):
There's pahoehoe:
...and there's a'a:
Here's a pahoehoe flow oozing over my boot (just kidding; it was cold when I did this):
Pahoehoe lobes can drain out, leaving only the outer skin as rock, but with a hollow center. These are lava tubes (nickel for scale):
Another one (nickel for scale):
Cool texture on the inside of this lava tube (nickel for scale):
...and zooming in a bit closer (it looks like wrinkled cellophane!):
A stack of cross-sectioned pahoehoe flows, showing their tubular (totally tubular, dude) shape:
Some Hawai'i basalt is massive, like this cobble...
...or like this cobble of hawaiite, a dense form of basalt found atop Mauna Kea (where it apparently erupted beneath Pleistocene ice caps):
But the majority of Hawai'i's basalts are vesicular, meaning they contain "Swiss Cheese" type holes that result from gas bubbles. When the lava erupts, it experiences less pressure at the Earth's surface than it was subjected to at depth. As a result, many gases (steam, CO2, sulfur dioxide, chlorine, argon, others) exsolve from the lava solution and make bubbles. If these bubbles don't get a chance to pop before the lava sets up into igneous rock, then they are preserved as vesicles. Sometimes the vesicles are small:
...and sometimes they are big:
Sometimes, they are really big. Here's one I could fit my entire Nalgene water bottle into:
When vesicles later get filled in with mineral deposits, we call them amygdules. Here's some vesicles that have gotten a light coat of a white mineral on their interiors: the first step to converting a vesicle into an amygdule:
Some of the vesicles show strain (almost certainly due to late-stage flow in the increasingly-viscous lava, getting stretched out like air bubbles in pouring honey). Surface tension on the bubble wants to make it spherical, and the lower the lava's viscosity, the easier it will be to attain that perfect spherical shape, minimizing the surface-area-to-volume ratio. So when we find them in cigar-shapes or pancake-shapes instead, that's a clue that they've been deformed. Deformed not by tectonic forces (ductile flow at depth in an orogen), but ductile flow as a result of their formation, in a sluggishly oozing blob of lava:
Another example of stretched-out vesicles:
A lonely vesicle in an otherwise massive basalt:
Not sure what's going on here, but it looks cool (popped vesicles in sticky lava?):
Another thing you see a lot of in these Hawai'ian basalts are phenocrysts of certain minerals. Here, for instance, is a cobble showing nice olivine phenocrysts:
...and another:
Here's one I showed you last week when we discussed Green Sands Beach:
Here's an outcrop which shows phenocrysts of plagioclase feldspar instead:
And a river cobble (also vesicular) bearing a healthy population of feldspar phenocrysts:
Holy feldspar, Batman! This rock has a huge proportion of feldspars (you'll note that it's still vesicular, though: in spite of the overwhelming volume of macroscopic crystals, this is still an extrusive rock):
Here's something else caught up in a finer grained (and yes, vesicular) basaltic matrix: another piece of basalt!
This is a xenolith of slightly-older basalt showing flow banding in its own trains of vesicles, that after solidification got broken off and included in younger flows of basalt. I'll post some additional xenolith photos later this week.
It's not all basalt, though. Here's a breccia made of basaltic cobbles (penny for scale):
And a closer shot of the same outcrop (penny for scale):
Finally, a rock I was surprised to see: an intermediate-composition extrusive igneous rock called benmoreite (nickel for scale, and note the rock hammer impact marks):
Benmoreite is way more felsic that anything else on the island. According to my volcanic advisor Jess, it's the result of late-stage partial melting of basaltic source rocks in the island's oldest volcano, Kohala. In other words, it's a distillation of basalt: concentrating the most felsic components in this decidedly-lighter-complected rock (nickel for scale):
Labels: basalt, geology, hawaii, igneous, national parks, pleistocene, primary structures, volcano, xenoliths
5 Comments:
Great boot trick!
Is the benmoreite related to any of the weird volcanic rocks on Mauna Kea? I've never heard of Kohala (or benmoreite) - always good to find out something new.
What qualifies as "weird" on Mauna Kea?
It was the first time I'd heard of benmoreite too. Jess of Magma Cum Laude can probably tell you more than I can. It was she who alerted me to it.
Kohala is the oldest and northwesternmost of the five volcanoes that make up the big island. In order of decreasing age, these five are: Kohala, Mauan Kea, Hualalai, Mauna Loa, and Kilauea.
Oops - misspelled "Mauna" Kea in the previous comment.
Actually, this says Mauna Kea has some benmoreite, along with alkalic lavas (which is kind of general), but I remember some other unusual volcanic rock names, would have to google a bit more. Also, this mentions some tonalite and diorite xenoliths.
Maybe the "weird" ones had high K? I'll have to look into that...
Trachyte, maybe? I heard that mentioned a lot (by the staff at HVO, and in The Roadside Geology of Hawai'i, but I don't know that I actually saw any during my visit.
I've got some cool images of xenoliths (from Mauna Kea, and elsewhere) that I'll share here later this week.
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