When are tides highest? a. during the moon’s first quarter phase b. when the sun, Earth, and the moon are nearly in a line c. during the moon’s third quarter phase d. when the moon is at a right angle to the sun

Answers

Answer 1

Answer:

Answer:

The correct answer is option b, that is, when the Sun, Earth, and the moon are nearly in a line.

Explanation:

The low and high tides are caused by the moon. The gravitational force of the moon produces something known as the tidal force. This force makes the Earth and its water to bulge out on the side nearest to the moon and the side far away from the moon. These bulges of water are considered as high tides.

Similarly to the moon, the Sun also causes tides, but, they are smaller in comparison. However, when the Earth, moon, and the Sun line up, that is, which takes place during the new moon or the full moon, the solar and lunar tides reinforce each other, resulting in more extreme tides, known as spring tides. The spring tides are considered as the highest tides.

Answer 2

Answer: The answer is B. when the sun,earth, and the moon are nearly in a line

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Which type of crystal is typified by a sea of delocalized electronssurrounding the lattice?
O A. lonic
B. Metallic
OC. Macromolecular
D. Chemical
Reset Selection

Answers

The correct answer is option B. Metallic.

What explains the structure of metals and delocalized electrons?

Metal is composed of a huge structure of atoms arranged in a regular pattern. Electrons from the outer shell of a metal atom are delocalized and can move freely throughout the structure. This sharing of delocalized electrons results in strong metal bonds.

Metallic bonds are electrostatic attraction between metal cations and the negatively charged ocean of delocalized electrons. The sea of delocalized electrons contains only valence electrons, not core electrons.

Learn more about Metal here: brainly.com/question/4701542

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B.metallic is the answer hope this helped

How does a solid become a liquid

Answers

Well, one way a solid can turn into a liquid is by melting...
Lets say we have an ice cube... An ice cube, is a solid. And if that melts, what happens? Well, It turns into a liquid...
How does it melt, you may ask... Well, if you apply heat to the ice, then it turns into water, in which its a liquid.
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Hope this helped! Anymore questions, please feel free to ask!

The only way a solid can turn into a liquid is by melting. When you get a solid hot, the molecules bump around faster and harder until they start breaking apart and moving around each other; that's when a solid melts and becomes a liquid.
Hope this helps!

If you were to observe a handful of soil, what materials would you MOST LIKELY find? A. weathered rock and decomposed organic remains
B. small pieces of recycled glass and tiny pebbles
C. large minerals and fossilized remains of organisms
D. small living plants and hardened lava from a volcano

Answers

Your answer is A. Weathered rocks and decomposed organic remains.

You want to prepare a solution with a concentration of 200.0μM from a stock solution with a concentration of 500.0mM. At your disposal, you have 5-mL and 10-mL transfer pipets and volumetric flasks of sizes 100, 250, 500, and 1000mL. Which of the following serial dilutions will give you the 200.0μM solution?

Answers

Answer:

1) The dilution scheme will result in a 200μM solution.

2) The dilution scheme will not result in a 200μM solution.

3) The dilution scheme will not result in a 200μM solution.

4) The dilution scheme will result in a 200μM solution.

5) The dilution scheme will result in a 200μM solution.

Explanation:

Convert the given original molarity to molar as follows.

$500mM = 500mM * ((1M)/(1000M))= 0.5M$

Consider the following serial dilutions.

Dilute 5.00 mL of the stock solution upto 500 mL . Then dilute 10.00 mL of the resulting solution upto 250.0 mL.

Molarity of 500 mL solution:

$M_(2)= (M_(1)V_(1))/(V_(2))= ((0.5M)(5.00mL))/(500 mL)= 5 * 10^(-3)M$

10 mL of this solution is diluted to 250 ml

$M_(final)= (M_(2)V_(2))/(V_(final))= ((5 * 10^(-3)M)(10.0mL))/(250 mL)= 2 * 10^(-4)M$

Convert μM :

$2 * 10^(-4)M = (2 * 10^(-4)M)((1 \mu M)/(10^(-6)M))= 200 \mu M$

Therefore, The dilution scheme will result in a 200μM solution.

Dilute 5.00 mL of the stock solution upto 100 mL . Then dilute 10.00 mL of the resulting solution upto 1000 mL.

Molarity of 100 mL solution:

$M_(2)= (M_(1)V_(1))/(V_(2))= ((0.5M)(5.00mL))/(100 mL)= 2.5 * 10^(-2)M$

10 mL of this solution is diluted to 1000 ml

$M_(final)= (M_(2)V_(2))/(V_(final))= ((2.5 * 10^(-2)M)(10.0mL))/(1000 mL)= 2.5 * 10^(-4)M$

Convert μM :

$2.5 * 10^(-4)M = (2.5 * 10^(-4)M)((1 \mu M)/(10^(-6)M))= 250 \mu M$

Therefore, The dilution scheme will not result in a 200μM solution.

Dilute 10.00 mL of the stock solution upto 100 mL . Then dilute 5 mL of the resulting solution upto 100 mL.

Molarity of 100 mL solution:

$M_(2)= (M_(1)V_(1))/(V_(2))= ((0.5M)(10mL))/(100 mL)= 0.05M$

5 mL of this solution is diluted to 1000 ml

$M_(final)= (M_(2)V_(2))/(V_(final))= ((0.05M)(5mL))/(1000 mL)= 0.25 * 10^(-4)M$

Convert μM :

$0.25 * 10^(-4)M = (0.25 * 10^(-4)M)((1 \mu M)/(10^(-6)M))= 25 \mu M$

Therefore, The dilution scheme will not result in a 200μM solution.

Dilute 5 mL of the stock solution upto 250 mL . Then dilute 10 mL of the resulting solution upto 500 mL.

Molarity of 250 mL solution:

$M_(2)= (M_(1)V_(1))/(V_(2))= ((0.5M)(5mL))/(250 mL)= 0.01M$

10 mL of this solution is diluted to 500 ml

$M_(final)= (M_(2)V_(2))/(V_(final))= ((0.01M)(10mL))/(500 mL)= 2 * 10^(-4)M$

Convert μM :

$2 * 10^(-4)M = (2 * 10^(-4)M)((1 \mu M)/(10^(-6)M))= 200 \mu M$

Therefore, The dilution scheme will result in a 200μM solution.

Dilute 10 mL of the stock solution upto 250 mL . Then dilute 10 mL of the resulting solution upto 1000 mL.

Molarity of 250 mL solution:

$M_(2)= (M_(1)V_(1))/(V_(2))= ((0.5M)(10mL))/(250 mL)= 0.02M$

10 mL of this solution is diluted to 1000 ml

$M_(final)= (M_(2)V_(2))/(V_(final))= ((0.02M)(10mL))/(1000 mL)= 2 * 10^(-4)M$

Convert μM :

$2 * 10^(-4)M = (2 * 10^(-4)M)((1 \mu M)/(10^(-6)M))= 200 \mu M$

Therefore, The dilution scheme will result in a 200μM solution.

Which of the following measures the radiation given off by atoms per second?

Answers

The answer is curie.

the answer is curie

curie- a unit of radiation equal 3.7x10^10 disintegratons persecond

Beverly and Carl are in a race. Their graphs show the data Which best describes the race?A. Even though for a majority of the race they accelerated at the same rate, Carl won because his initial acceleration was greater than Beverly’s
B. Even though for a majority of the race they accelerated at the same rate, Beverly won because her initial acceleration was greater than Carl’s.
C.Beverly accelerated at a greater rate for the entire race.
D. Carl accelerated at a greater rate for the entire race

Answers

The correct option is B.

Acceleration is defined as the rate of velocity of a body per unit time; that is, acceleration is given by the ratio of velocity and time. Looking at the graph given above, it can be seen that, the two runners started with different initial velocity; Beverly started with the initial velocity of 15 m/s while Carl started with the initial velocity of 10 m/s. For the rest of the race, the two runners maintains similar acceleration but Beverly won because her initial velocity was higher.

The correct answer is B
i just finished the test. hope this helps

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