Do you have to write a paragraph for each one
Explanation:
The frictional resistance of the various pipes are given by the
K value in the table which may be used with the formula
hf = KQ2
to relate the magnitude of head loss hf in the pipeline
to the volumetric flow rate, Q. Water is drawn at the constant flow
rates from the network at nodes C and D. The static heads
(elevation + pressure head) at nodes B, C and D are 100m, 65m
and 61m respectively above the local datum. Calculate the
discharges at C and D and the water level in reservoir A. (The
data has been added to the diagram to aid the solution)
Use no more than 3 iterations and 3 significant figures.
The five states of matter and energy are related are:
- Solids
- Liquids
- Gases
- Plasmas
- Bose-Einstein condensates (BEC)
<h3 />
The states of matter is known to be related to energy because Energy is said to be a property that matter has.
Note that the same amount matter is one that is able to have different levels or amounts of energy and so this tends to stands for different states of matter. E.g., if a person add energy to an ice cube that has been created with water, it tends to become liquid water, and if when one also add even more energy, it tends to become steam.
<h3>What are the 5 states of matter?</h3>
The five states of matter are known to be Solids, liquids, and others listed above. They tend to have different physical properties.
Note that Solids are often seen to be hard while liquids are known to be that which fill containers, and gases are said to often surround our environment and in the air.
Note that matter change through the adding and the removing of energy from matter and this is one that leads to a physical change as matter is known to moves from one form to another.
Hence, The five states of matter and energy are related are:
- Solids
- Liquids
- Gases
- Plasmas
- Bose-Einstein condensates (BEC)
Learn more about matter from
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Answer:
Hi!
Explanation:
I would like points, please!
Answer:
Approximately 22,000 metric tonnes of fish per year
Explanation:
From the graph,
Rate of decline :
(metric tonnes of fish in 1965 - metric tonnes of fish in 1995) / range of years
(700,000 - 40,000)metric tonnes ÷ (1995 - 1965)
660,000 metric tonnes ÷ 30 years
660,000 / 30
= 22,000 metric tonnes per year
Approximately 22,000 metric tonnes of fish per year
