Difference between revisions of "AY Honors/Rocks & Minerals/Answer Key"

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< AY Honors‎ | Rocks & MineralsAY Honors/Rocks & Minerals/Answer Key
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{{Honor_Master|honor=Rocks &#38; Minerals|master=Conservation}}
 
{{Honor_Master|honor=Rocks &#38; Minerals|master=Conservation}}
  
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<!--T:2-->
 
{{IAConnection|[[Investiture_Achievement/Guide/Nature_Study|GUIDE Nature Study]]|(as one of two options) collecting and identifying 15 different kinds of rocks and minerals which meets Requirement 2 of this Honor|This Honor is a popular choice for the Level 2 or 3 Nature Honor required of FRONTIER GUIDES.}}
 
{{IAConnection|[[Investiture_Achievement/Guide/Nature_Study|GUIDE Nature Study]]|(as one of two options) collecting and identifying 15 different kinds of rocks and minerals which meets Requirement 2 of this Honor|This Honor is a popular choice for the Level 2 or 3 Nature Honor required of FRONTIER GUIDES.}}
  
==1. Distinguish between rocks and minerals.==
+
==1. Distinguish between rocks and minerals.== <!--T:3-->
 
A mineral is a naturally occurring, inorganic solid with a definite chemical composition and a crystalline structure formed by geological processes.  A rock is an aggregate of one or more minerals. (A rock may also include organic remains and mineraloids.) Some rocks are predominantly composed of just one mineral. For example, limestone is a sedimentary rock composed almost entirely of the mineral calcite. Other rocks contain many minerals, and the specific minerals in a rock can vary widely. Some minerals, like quartz, mica or feldspar are common, while others have been found in only one or two locations worldwide.
 
A mineral is a naturally occurring, inorganic solid with a definite chemical composition and a crystalline structure formed by geological processes.  A rock is an aggregate of one or more minerals. (A rock may also include organic remains and mineraloids.) Some rocks are predominantly composed of just one mineral. For example, limestone is a sedimentary rock composed almost entirely of the mineral calcite. Other rocks contain many minerals, and the specific minerals in a rock can vary widely. Some minerals, like quartz, mica or feldspar are common, while others have been found in only one or two locations worldwide.
 
==2. Have a collection of at least fifteen specimens correctly named. Label each specimen with collector's name, date, and locality in which it was found.==
 
==2. Have a collection of at least fifteen specimens correctly named. Label each specimen with collector's name, date, and locality in which it was found.==
 
Identifying rocks and minerals is best done with a Field Guide.  The following properties are very useful for identification purposes:
 
Identifying rocks and minerals is best done with a Field Guide.  The following properties are very useful for identification purposes:
  
 +
<!--T:4-->
 
* Hardness
 
* Hardness
 
* Cleavage
 
* Cleavage
Line 28: Line 31:
 
* Crystalline structure
 
* Crystalline structure
  
 +
<!--T:5-->
 
These are described in detail in requirements 4 and 5.
 
These are described in detail in requirements 4 and 5.
  
 +
<!--T:6-->
 
You will need a few tools for measuring various aspects of rocks.  Not all of them are required, but the more of them that are available to you, the more successful you will be in identifying specimens.
 
You will need a few tools for measuring various aspects of rocks.  Not all of them are required, but the more of them that are available to you, the more successful you will be in identifying specimens.
  
 +
<!--T:7-->
 
* Specific Gravity meter
 
* Specific Gravity meter
 
* Ceramic tile for determining "scratch" color
 
* Ceramic tile for determining "scratch" color
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** Steel file
 
** Steel file
  
==3. Define and name two examples each (from specimens or pictures) of: ==
+
==3. Define and name two examples each (from specimens or pictures) of: == <!--T:8-->
 
===a. Igneous===  
 
===a. Igneous===  
 
;Igneous: Igneous rock is formed when lava cools and solidifies.
 
;Igneous: Igneous rock is formed when lava cools and solidifies.
Line 52: Line 58:
 
</gallery>
 
</gallery>
  
===b. Sedimentary ===
+
===b. Sedimentary === <!--T:9-->
 
;Sedimentary: Sedimentary rock is formed when sediments carried by wind or water settle and turn to stone.
 
;Sedimentary: Sedimentary rock is formed when sediments carried by wind or water settle and turn to stone.
 
<gallery>
 
<gallery>
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</gallery>
 
</gallery>
  
==4. What is meant by Mohs' scale of hardness? Name the minerals in order in Mohs' scale. ==
+
==4. What is meant by Mohs' scale of hardness? Name the minerals in order in Mohs' scale. == <!--T:10-->
 
The Mohs scale of mineral hardness characterizes the scratch resistance of various minerals through the ability of a harder material to scratch a softer material. It was created in 1812 by the German mineralogist Friedrich Mohs and is one of several definitions of hardness in materials science.
 
The Mohs scale of mineral hardness characterizes the scratch resistance of various minerals through the ability of a harder material to scratch a softer material. It was created in 1812 by the German mineralogist Friedrich Mohs and is one of several definitions of hardness in materials science.
  
 +
<!--T:11-->
 
Mohs based the scale on ten minerals that are all readily available. As the hardest known naturally occurring substance, diamond is at the top of the scale. The hardness of a material is measured against the scale by finding the hardest material that the given material can scratch, and/or the softest material that can scratch the given material. For example, if some material is scratched by apatite but not by fluorite, its hardness on the Mohs scale is 4.5.
 
Mohs based the scale on ten minerals that are all readily available. As the hardest known naturally occurring substance, diamond is at the top of the scale. The hardness of a material is measured against the scale by finding the hardest material that the given material can scratch, and/or the softest material that can scratch the given material. For example, if some material is scratched by apatite but not by fluorite, its hardness on the Mohs scale is 4.5.
  
 +
<!--T:12-->
 
The Mohs scale is a purely ordinal scale. For example, corundum (9) is twice as hard as topaz (8), but diamond (10) almost four times as hard as corundum. The table below shows comparison with absolute hardness measured by a sclerometer.
 
The Mohs scale is a purely ordinal scale. For example, corundum (9) is twice as hard as topaz (8), but diamond (10) almost four times as hard as corundum. The table below shows comparison with absolute hardness measured by a sclerometer.
  
 +
<!--T:13-->
 
{| class="wikitable"
 
{| class="wikitable"
 
|-
 
|-
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 +
<!--T:14-->
 
On the Mohs scale, fingernail has hardness 2.5; copper penny, about 3.5; a knife blade, 5.5; window glass, 6.5; steel file, 6.5. Using these ordinary materials of known hardness can be a simple way to approximate the position of a mineral on the scale.
 
On the Mohs scale, fingernail has hardness 2.5; copper penny, about 3.5; a knife blade, 5.5; window glass, 6.5; steel file, 6.5. Using these ordinary materials of known hardness can be a simple way to approximate the position of a mineral on the scale.
  
 +
<!--T:15-->
 
Some mnemonics traditionally taught to geology students to remember this table are "The Girls Can Flirt And Other Queer Things Can Do" or "To Get Candy From Aunt Fanny, Quit Teasing Cousin Danny". Another Mnemonic is "Two Gypsies Called Flo And Fred Queued To Cut Diamonds."
 
Some mnemonics traditionally taught to geology students to remember this table are "The Girls Can Flirt And Other Queer Things Can Do" or "To Get Candy From Aunt Fanny, Quit Teasing Cousin Danny". Another Mnemonic is "Two Gypsies Called Flo And Fred Queued To Cut Diamonds."
  
 +
<!--T:16-->
 
An alternative table is shown below which has been modified to incorporate additional substances that may fall in between two levels.
 
An alternative table is shown below which has been modified to incorporate additional substances that may fall in between two levels.
  
 +
<!--T:17-->
 
Source: American Federation of Mineralogical Societies: Mohs Scale of Mineral Hardness
 
Source: American Federation of Mineralogical Societies: Mohs Scale of Mineral Hardness
  
 +
<!--T:18-->
 
{| class="wikitable"
 
{| class="wikitable"
 
|-
 
|-
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|}
 
|}
  
==5. Define cleavage, specific gravity, luster, color, streak, texture, crystal.==
+
==5. Define cleavage, specific gravity, luster, color, streak, texture, crystal.== <!--T:19-->
 
The terms that follow have specific meaning in mineralogy, and are useful for identifying the type of a specimen of rock or mineral.  To the uneducated eye, a rock is a rock is a rock.  But if the following terms are understood, noted, and cross-checked against known values for various specimens, a positive identification can be made.
 
The terms that follow have specific meaning in mineralogy, and are useful for identifying the type of a specimen of rock or mineral.  To the uneducated eye, a rock is a rock is a rock.  But if the following terms are understood, noted, and cross-checked against known values for various specimens, a positive identification can be made.
 
===a. Cleavage ===
 
===a. Cleavage ===
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Specific gravity is the ratio of the density of a material relative to the density of water.  Density is the ratio of an object's mass to its volume.  For instance, we know that 1 cm^3 of water weighs 1 gram.  Therefore, the density of water is:
 
Specific gravity is the ratio of the density of a material relative to the density of water.  Density is the ratio of an object's mass to its volume.  For instance, we know that 1 cm^3 of water weighs 1 gram.  Therefore, the density of water is:
  
 +
<!--T:20-->
 
:<math>density_{water} = \frac{1 gram}{1 cm^3} = 1g/cm^3</math>
 
:<math>density_{water} = \frac{1 gram}{1 cm^3} = 1g/cm^3</math>
  
 +
<!--T:21-->
 
A cubic centimeter of diamond would weigh 3.52 grams, so we can calculate the density of diamond as:
 
A cubic centimeter of diamond would weigh 3.52 grams, so we can calculate the density of diamond as:
  
 +
<!--T:22-->
 
:<math>density_{diamond} = \frac{3.52 grams}{1 cm^3} = 3.52g/cm^3</math>
 
:<math>density_{diamond} = \frac{3.52 grams}{1 cm^3} = 3.52g/cm^3</math>
  
 +
<!--T:23-->
 
Finally, we can calculate the specific gravity (G) of diamond:
 
Finally, we can calculate the specific gravity (G) of diamond:
  
 +
<!--T:24-->
 
:<math>G = \frac{density_{specimen}}{density_{water}} = \frac{3.52g/cm^3}{1g/cm^3} = 3.52</math>
 
:<math>G = \frac{density_{specimen}}{density_{water}} = \frac{3.52g/cm^3}{1g/cm^3} = 3.52</math>
  
 +
<!--T:25-->
 
Division by 1 is a lovely thing!
 
Division by 1 is a lovely thing!
  
 +
<!--T:26-->
 
What this really boils down to is that any given volume of diamond will weigh 3.52 times more than an equal volume of water.  If you know the specific gravity, <math>G</math> of any material, you will know that it weighs <math>G</math> times an equal volume of water.
 
What this really boils down to is that any given volume of diamond will weigh 3.52 times more than an equal volume of water.  If you know the specific gravity, <math>G</math> of any material, you will know that it weighs <math>G</math> times an equal volume of water.
  
 +
<!--T:27-->
 
But what use is specific gravity?  It helps us identify a mineral.  We can measure a sample's specific gravity and compare it to the specific gravities of known specimens.  To do this, we will need to make two measurements: the weight of the specimen, and its volume.  Weight is easy (assuming you have a scale or a balance that can measure grams), but how do you measure the volume of an irregularly shaped specimen?  All you need is some water, a drop of dish soap, and a graduated  cylinder marked in metric units (note that 1 milliliter equals 1 cubic centimeter).  Put some water in the cylinder, adding enough until the level comes to a convenient, well-marked level (such as 100 ml).  Add a drop of dish soap to break the surface tension (you won't need more than a tiny drop).  Then drop the specimen into the water and note the new water level.  Subtracting the new level from the old will give you the volume of the specimen.  Now all you need to do is divide the weight in grams by the volume in milliliters.
 
But what use is specific gravity?  It helps us identify a mineral.  We can measure a sample's specific gravity and compare it to the specific gravities of known specimens.  To do this, we will need to make two measurements: the weight of the specimen, and its volume.  Weight is easy (assuming you have a scale or a balance that can measure grams), but how do you measure the volume of an irregularly shaped specimen?  All you need is some water, a drop of dish soap, and a graduated  cylinder marked in metric units (note that 1 milliliter equals 1 cubic centimeter).  Put some water in the cylinder, adding enough until the level comes to a convenient, well-marked level (such as 100 ml).  Add a drop of dish soap to break the surface tension (you won't need more than a tiny drop).  Then drop the specimen into the water and note the new water level.  Subtracting the new level from the old will give you the volume of the specimen.  Now all you need to do is divide the weight in grams by the volume in milliliters.
  
===c. Luster ===
+
===c. Luster === <!--T:28-->
 
{{:Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Luster}}
 
{{:Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Luster}}
  
===d. Color ===
+
===d. Color === <!--T:29-->
 
'''Color''' indicates the appearance of the mineral in reflected light (for opaque specimens) or transmitted light (for translucent specimens).  In other words, it means just what you would think it means -  what it looks like to the naked eye.  Before noting the color of a specimen, it is important to clean it off.
 
'''Color''' indicates the appearance of the mineral in reflected light (for opaque specimens) or transmitted light (for translucent specimens).  In other words, it means just what you would think it means -  what it looks like to the naked eye.  Before noting the color of a specimen, it is important to clean it off.
  
===e. Streak ===
+
===e. Streak === <!--T:30-->
 
{{:Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Streak}}
 
{{:Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Streak}}
  
===f. Texture ===
+
===f. Texture === <!--T:31-->
 
Texture in geology refers to the physical appearance or character of a rock, such as grain size, shape, and arrangement, both to the naked eye and under a microscope.
 
Texture in geology refers to the physical appearance or character of a rock, such as grain size, shape, and arrangement, both to the naked eye and under a microscope.
  
===g. Crystal ===
+
===g. Crystal === <!--T:32-->
 
[[Image:Quartz Crystal.jpg|thumb|Quartz crystal]]
 
[[Image:Quartz Crystal.jpg|thumb|Quartz crystal]]
 
A crystal is a solid whose atoms, molecules, or ions are packed in a regularly ordered, repeating pattern extending in all three spatial dimensions.  Snowflakes, diamonds, and common salt are common examples of crystals.
 
A crystal is a solid whose atoms, molecules, or ions are packed in a regularly ordered, repeating pattern extending in all three spatial dimensions.  Snowflakes, diamonds, and common salt are common examples of crystals.
 
<br style="clear:both">
 
<br style="clear:both">
  
==6. Name four uses for rocks and four uses for minerals. ==
+
==6. Name four uses for rocks and four uses for minerals. == <!--T:33-->
 
===Uses for Rock===
 
===Uses for Rock===
 
* Building material
 
* Building material
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* Ores (most metals are extracted from ore)
 
* Ores (most metals are extracted from ore)
  
===Uses for Minerals===
+
===Uses for Minerals=== <!--T:34-->
 
* Abrasives (diamond dust, garnet, others)
 
* Abrasives (diamond dust, garnet, others)
 
* Lasers (sapphire, ruby)
 
* Lasers (sapphire, ruby)
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;{{Bible link|Acts 6-7}}: The stoning of Stephen
 
;{{Bible link|Acts 6-7}}: The stoning of Stephen
  
==8. What are the foundation stones of the New Jerusalem?==
+
==8. What are the foundation stones of the New Jerusalem?== <!--T:35-->
 
[http://www.biblegateway.com/passage/?search=Revelation%2021:19-20;&version=31; Revelation 21:19,20] describes the foundation stones of the New Jerusalem.
 
[http://www.biblegateway.com/passage/?search=Revelation%2021:19-20;&version=31; Revelation 21:19,20] describes the foundation stones of the New Jerusalem.
 
<gallery>
 
<gallery>
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</gallery>
 
</gallery>
  
 +
<!--T:36-->
 
The wall has twelve foundation stones, and on these are written the names of the Twelve Apostles.  Revelation lacks a list of the names of the Twelve Apostles, and does not describe which name is inscribed on which foundation stone, or if all of the names are inscribed on all of the foundation stones, so that aspect of the arrangement is open to speculation.  One scholar hold that Judas Iscariot's name is absent from the foundations, replaced by that of another Apostle.
 
The wall has twelve foundation stones, and on these are written the names of the Twelve Apostles.  Revelation lacks a list of the names of the Twelve Apostles, and does not describe which name is inscribed on which foundation stone, or if all of the names are inscribed on all of the foundation stones, so that aspect of the arrangement is open to speculation.  One scholar hold that Judas Iscariot's name is absent from the foundations, replaced by that of another Apostle.
  
 +
<!--T:37-->
 
These foundation stones are adorned with twelve types of precious stones.  In modern times, the precise identification of all these precious stones is not certain, as several of the ancient names  may refer to several different types of stones, or may no longer refer to the same kinds of stones that they did at the time of Revelation's writing.  Also, the layout of the precious stones is contested.  All of the precious stones could adorn each foundation stone, either in layers or mixed together some other way, or just one unique type of stone could adorn each separate foundation stone.
 
These foundation stones are adorned with twelve types of precious stones.  In modern times, the precise identification of all these precious stones is not certain, as several of the ancient names  may refer to several different types of stones, or may no longer refer to the same kinds of stones that they did at the time of Revelation's writing.  Also, the layout of the precious stones is contested.  All of the precious stones could adorn each foundation stone, either in layers or mixed together some other way, or just one unique type of stone could adorn each separate foundation stone.
  
==References==
+
==References== <!--T:38-->
 
'''Wikipedia Articles'''
 
'''Wikipedia Articles'''
 
*[[w:Mineral|Mineral]]
 
*[[w:Mineral|Mineral]]

Revision as of 02:27, 26 November 2014

Other languages:
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Template:Honor desc Template:Honor Master

Investiture Achievement Connection: This Honor is related to the Investiture Achievement requirements for GUIDE Nature Study which require (as one of two options) collecting and identifying 15 different kinds of rocks and minerals which meets Requirement 2 of this Honor. This Honor is a popular choice for the Level 2 or 3 Nature Honor required of FRONTIER GUIDES.


1. Distinguish between rocks and minerals.

A mineral is a naturally occurring, inorganic solid with a definite chemical composition and a crystalline structure formed by geological processes. A rock is an aggregate of one or more minerals. (A rock may also include organic remains and mineraloids.) Some rocks are predominantly composed of just one mineral. For example, limestone is a sedimentary rock composed almost entirely of the mineral calcite. Other rocks contain many minerals, and the specific minerals in a rock can vary widely. Some minerals, like quartz, mica or feldspar are common, while others have been found in only one or two locations worldwide.

2. Have a collection of at least fifteen specimens correctly named. Label each specimen with collector's name, date, and locality in which it was found.

Identifying rocks and minerals is best done with a Field Guide. The following properties are very useful for identification purposes:

  • Hardness
  • Cleavage
  • Specific gravity
  • Luster
  • Color
  • Streak
  • Texture
  • Crystalline structure

These are described in detail in requirements 4 and 5.

You will need a few tools for measuring various aspects of rocks. Not all of them are required, but the more of them that are available to you, the more successful you will be in identifying specimens.

  • Specific Gravity meter
  • Ceramic tile for determining "scratch" color
  • Magnifying glass
  • Hardness kit (you can use the following as a hardness kit as explained in requirement 4)
    • Fingernail
    • Copper penny
    • Knife blade
    • Window glass
    • Steel file

3. Define and name two examples each (from specimens or pictures) of:

a. Igneous

Igneous
Igneous rock is formed when lava cools and solidifies.

b. Sedimentary

Sedimentary
Sedimentary rock is formed when sediments carried by wind or water settle and turn to stone.

c. Metamorphic

Metamorphic
Metamorphic rock is formed when another type of rock is transformed by great heat and pressure.

4. What is meant by Mohs' scale of hardness? Name the minerals in order in Mohs' scale.

The Mohs scale of mineral hardness characterizes the scratch resistance of various minerals through the ability of a harder material to scratch a softer material. It was created in 1812 by the German mineralogist Friedrich Mohs and is one of several definitions of hardness in materials science.

Mohs based the scale on ten minerals that are all readily available. As the hardest known naturally occurring substance, diamond is at the top of the scale. The hardness of a material is measured against the scale by finding the hardest material that the given material can scratch, and/or the softest material that can scratch the given material. For example, if some material is scratched by apatite but not by fluorite, its hardness on the Mohs scale is 4.5.

The Mohs scale is a purely ordinal scale. For example, corundum (9) is twice as hard as topaz (8), but diamond (10) almost four times as hard as corundum. The table below shows comparison with absolute hardness measured by a sclerometer.

Hardness Mineral Absolute Hardness
1 Talc

(Mg3Si4O10(OH)2)

1
2 Gypsum (CaSO4·2H2O) 2
3 Calcite (CaCO3) 9
4 Fluorite (CaF2) 21
5 Apatite

(Ca5(PO4)3(OH-,Cl-,F-))

48
6 Orthoclase Feldspar (KAlSi3O8) 72
7 Quartz (SiO2) 100
8 Topaz (Al2SiO4(OH-,F-)2) 200
9 Corundum (Al2O3) 400
10 Diamond (C) 1500


On the Mohs scale, fingernail has hardness 2.5; copper penny, about 3.5; a knife blade, 5.5; window glass, 6.5; steel file, 6.5. Using these ordinary materials of known hardness can be a simple way to approximate the position of a mineral on the scale.

Some mnemonics traditionally taught to geology students to remember this table are "The Girls Can Flirt And Other Queer Things Can Do" or "To Get Candy From Aunt Fanny, Quit Teasing Cousin Danny". Another Mnemonic is "Two Gypsies Called Flo And Fred Queued To Cut Diamonds."

An alternative table is shown below which has been modified to incorporate additional substances that may fall in between two levels.

Source: American Federation of Mineralogical Societies: Mohs Scale of Mineral Hardness

Hardness Substance or Mineral
1 Talc
2 Gypsum
2.5 to 3 pure Gold, Silver
3 Calcite, Copper penny
4 Fluorite
4 to 4.5 Platinum
4 to 5 Iron
5 Apatite
6 Orthoclase
6.5 Iron pyrite
6 to 7 Glass, Vitreous pure silica
7 Quartz
7 to 7.5 Garnet
7 to 8 Hardened steel
8 Topaz
9 Corundum
10 Diamond
11.1 Aggregated diamond nanorods

5. Define cleavage, specific gravity, luster, color, streak, texture, crystal.

The terms that follow have specific meaning in mineralogy, and are useful for identifying the type of a specimen of rock or mineral. To the uneducated eye, a rock is a rock is a rock. But if the following terms are understood, noted, and cross-checked against known values for various specimens, a positive identification can be made.

a. Cleavage

Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Cleavage

b. Specific gravity

Specific gravity is the ratio of the density of a material relative to the density of water. Density is the ratio of an object's mass to its volume. For instance, we know that 1 cm^3 of water weighs 1 gram. Therefore, the density of water is:

[math]\displaystyle{ density_{water} = \frac{1 gram}{1 cm^3} = 1g/cm^3 }[/math]

A cubic centimeter of diamond would weigh 3.52 grams, so we can calculate the density of diamond as:

[math]\displaystyle{ density_{diamond} = \frac{3.52 grams}{1 cm^3} = 3.52g/cm^3 }[/math]

Finally, we can calculate the specific gravity (G) of diamond:

[math]\displaystyle{ G = \frac{density_{specimen}}{density_{water}} = \frac{3.52g/cm^3}{1g/cm^3} = 3.52 }[/math]

Division by 1 is a lovely thing!

What this really boils down to is that any given volume of diamond will weigh 3.52 times more than an equal volume of water. If you know the specific gravity, [math]\displaystyle{ G }[/math] of any material, you will know that it weighs [math]\displaystyle{ G }[/math] times an equal volume of water.

But what use is specific gravity? It helps us identify a mineral. We can measure a sample's specific gravity and compare it to the specific gravities of known specimens. To do this, we will need to make two measurements: the weight of the specimen, and its volume. Weight is easy (assuming you have a scale or a balance that can measure grams), but how do you measure the volume of an irregularly shaped specimen? All you need is some water, a drop of dish soap, and a graduated cylinder marked in metric units (note that 1 milliliter equals 1 cubic centimeter). Put some water in the cylinder, adding enough until the level comes to a convenient, well-marked level (such as 100 ml). Add a drop of dish soap to break the surface tension (you won't need more than a tiny drop). Then drop the specimen into the water and note the new water level. Subtracting the new level from the old will give you the volume of the specimen. Now all you need to do is divide the weight in grams by the volume in milliliters.

c. Luster

Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Luster

d. Color

Color indicates the appearance of the mineral in reflected light (for opaque specimens) or transmitted light (for translucent specimens). In other words, it means just what you would think it means - what it looks like to the naked eye. Before noting the color of a specimen, it is important to clean it off.

e. Streak

Adventist Youth Honors Answer Book/Nature/Rocks & Minerals/Streak

f. Texture

Texture in geology refers to the physical appearance or character of a rock, such as grain size, shape, and arrangement, both to the naked eye and under a microscope.

g. Crystal

Quartz crystal

A crystal is a solid whose atoms, molecules, or ions are packed in a regularly ordered, repeating pattern extending in all three spatial dimensions. Snowflakes, diamonds, and common salt are common examples of crystals.

6. Name four uses for rocks and four uses for minerals.

Uses for Rock

  • Building material
  • Gravel
  • Paving stones
  • Grinding grain into meal (millstones)
  • Sharpening blades (whetstones)
  • Sculpture medium (marble, granite, others)
  • Fill material
  • Fuel (coal)
  • Ores (most metals are extracted from ore)

Uses for Minerals

  • Abrasives (diamond dust, garnet, others)
  • Lasers (sapphire, ruby)
  • Electronics (semiconductors)
  • Lenses (quartz)
  • Nutrition (your body needs many minerals)
  • Traction (silica - also known as sand)
  • Currency (gold, silver, copper)
  • Pencil lead (graphite)
  • Lubricant (graphite)
  • Medicine (Kaopectate is made from the mineral kaolin)

7. Tell of four Bible incidents in which a rock was significant.

Exodus 24:16-18
God carves the ten commandments in stone.
Numbers 20:2-13
God commands Moses to speak to the rock to provide water for the Isrealites but Moses hits it instead.
1 Samuel 17
David kills Goliath with a stone.
Daniel 2:34
A stone is cut without hands and destroys the image in Daniel's dream.
John 11:38-44
Jesus orders that the stone covering the tomb of Lazarus be removed.
Matthew 7:24-29
The parable of the wise and foolish builders.
Acts 6-7
The stoning of Stephen

8. What are the foundation stones of the New Jerusalem?

Revelation 21:19,20 describes the foundation stones of the New Jerusalem.

The wall has twelve foundation stones, and on these are written the names of the Twelve Apostles. Revelation lacks a list of the names of the Twelve Apostles, and does not describe which name is inscribed on which foundation stone, or if all of the names are inscribed on all of the foundation stones, so that aspect of the arrangement is open to speculation. One scholar hold that Judas Iscariot's name is absent from the foundations, replaced by that of another Apostle.

These foundation stones are adorned with twelve types of precious stones. In modern times, the precise identification of all these precious stones is not certain, as several of the ancient names may refer to several different types of stones, or may no longer refer to the same kinds of stones that they did at the time of Revelation's writing. Also, the layout of the precious stones is contested. All of the precious stones could adorn each foundation stone, either in layers or mixed together some other way, or just one unique type of stone could adorn each separate foundation stone.

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