Technically all 3 can make up each Sedimentary, Metamorphic, and Igneous.
But the process of metamorphosis is really kinda of linear, and you can only metamorphose a Metamorphic further, so the answer to your question would really be:
Igneous and Metamorphic.
Here is the explanation of the Rock Cycle:
# Magma cools to form igneous rock after a volcanic event.
# Igneous rock undergoes weathering to form sediment. The sediment is taken somewhere and deposited. (i.e. the beach, delta, bottom of a body of water or in sand dunes). # The deposited sediment undergoes a the processes that turns it into a rock). (i.e. cementation (think of concrete hardening, but over a much longer period of time) and compaction.)
# As the Sedimentary rock becomes buried under more sediment, it goes deeper into the earth. The heat and pressure cause metamorphism to occur. This transforms the sedimentary rock into a Metam orphic rock. This can also happen by a force called Subduction. This happens when one tectonic plate rides up on the other, forcing the lower plate to be pushed deep into the earth. This will happen to the point where it melts and become Magma (see #1)
# As the metamorphic rock is buried more deeply (or as it is squeezed by increasing subduction depths), temperatures and pressures will keep rising. when the temperature becomes hot enough, the metamorphic rock melts. The molten rock once again magma. Thus finishing the cycle, starting back at #1.
Given that information. There are shortcuts.
# Any rock type can be weathered forming sediments, followed by transportation and deposition of the sediment. Metamorphic and Sedimentary rocks can also undergo weathering/erosion. 2. Igneous rocks can undergo metamorphism (with added heat and pressure) to become metamorphic rocks.
So Therefore,
Igneous rock can be eroded into sediments, Ultimately becoming Sedimentary rock. And it can also be metamorphosed by heat and pressure, becoming a Metamorphic Rock before being melted into Igneous.
Sedimentary Rock can also be eroded into sediments, Ultimately becoming another Sedimentary rock. And it can also be metamorphosed by heat and pressure, becoming a Metamorphic Rock before being melted into Igneous.
Metamorphic Rock can be eroded into sediments, Ultimately becoming Sedimentary rock. And it can also be metamorphosed farther by heat and pressure, becoming another type of Metamorphic Rock in the line before being melted into Igneous.
1000 square feet is equal to approximately 92.9 square meters.
Yes I can. 1 metre = 3.28084 foot (rounded) (1m) times (1m) = 1 square metre (1m) times (1m) = (3.28084ft) times (3.28084ft) = 10.764 square feet (rounded) In the other direction, 1 square foot = 0.0929 square metre
To convert cubic meters to square feet, you need to have a third dimension. But if we assume that the height is 1 meter, then 3.7 cubic meters would be approximately 39.8 square feet.
Symmetrical faults occur when all three phases of a power system experience a fault condition simultaneously. These faults are characterized by symmetrical components having equal magnitude and displaced by 120 degrees from each other. Common types include three-phase short circuits and line-to-line faults.
Remember K H D | d c m (kilo, hecto, deka, (liter, meter, gram), deci, centi, milli). These are the denominations you need to list when converting metric units. Liters are three places to the left of milliliters. So you have to move the decimal place three times to the left (same as dividing by 1000). You will get 170 mL = .170 L.
To convert milligrams to microliters, you would first need to know the density of the substance in question. Once you have the density, you can use the formula: volume (µL) = mass (mg) / density (mg/µL). Without knowing the density, you cannot accurately convert milligrams to microliters.
Many things are available by the hectogram. A hectogram is about 100 grams which is about 3.527 ounces. A hundred grams is a standard common measurements of weight used in commerce where the metric system is in use.
In the US, packaged goods are commonly sold by the pound or 16 ounces (ie. a pound of peas, beans, cookies, fruit) or a multiple of pounds.
Where the metric system is in use, packages of good are commonly sold by the hectogram. Although that word is generally not used, goods are available in 100 gram amounts or multiples or submultiples of 100 grams. You can get 100 gram package of coffee beans or other kinds of beans or rice.
This is the radius of the circle. It connects the center of the circle to any point on the circumference. The length of the radius is constant for a given circle.
To convert grams to decigrams, you simply move the decimal point one place to the left. Therefore, 493.3 g is equivalent to 4933 dg.
Yes, Mars has cliffs. Some of the most prominent cliffs on Mars are found in Valles Marineris, a massive canyon system that stretches over 2,500 miles long and averages about 5 miles in depth. These cliffs are thought to have formed through a combination of tectonic and erosional processes.
1 meter is about 39.37 inches which mean yes a meter is bigger than an inch.......
144cm is equal to 1.44 meters. 1 meter is equal to 100 centimeters, so to convert centimeters to meters you need to divide by 100.
You use litres to measure the capacity of a car's gas tank.
Bond yield is the return an investor earns on a bond investment, expressed as a percentage of the bond's market price or face value. It takes into account both the interest payments received from the bond and any potential capital gains or losses upon its maturity. Bond yield helps investors assess the profitability and risk of investing in a particular bond.
Decimal is a numerical system based on powers of 10, whereas centimeter is a unit of measurement for length in the metric system. Decimals can represent fractional parts of a whole number, while centimeters measure distances in relation to a meter.
The smallest number of nucleotides that must be added or subtracted to alter the reading frame is 1. A single nucleotide insertion or deletion can cause a frameshift mutation, resulting in a different reading frame for translation.
The solution to the Heat equation using Fourier transform is given by the convolution of the initial condition with the fundamental solution of the heat equation, which is the Gaussian function. The Fourier transform helps in solving the heat equation by transforming the problem from the spatial domain to the frequency domain, simplifying the calculations.