The correct capatilization for it is Eighty-Second Street
Yes, that is correct.
The correct answer is 1.36
No. Only if you want to get the correct answer.
There are two reasons for this. The first is that a Fahrenheit degree is smaller than a Celsius degree. Four Celsius degrees is the same size as nine Fahrenheit degrees. The second reason is that 32 degrees Fahrenheit is zero degrees Celsius. If you put those two ideas together you figure out that -40°F = -40°C.
63.9 ml per joules a second. In the arctic sea only.
To convert joule per hour to joule per gram, you need a material's specific heat capacity. Multiply the joules per hour by 3600 (since there are 3600 seconds in an hour) to get joules per second. Then divide by the specific heat capacity of the material in joules per gram per degree Celsius to obtain joules per gram.
The second is correct. The second is correct. The second is correct. The second is correct.
To find the unknown initial temperature of the second sample of water, you can use the principle of conservation of energy. The heat lost by the first sample as it cools down will be equal to the heat gained by the second sample as it warms up. The specific heat capacity of water is 4.184 J/g°C. Just plug the values into the formula: (m_1c_1(T_f-T_1) = -m_2c_2(T_f-T_2)) where (m) is mass, (c) is specific heat, (T_f) is final temperature, and (T) is initial temperature.
Giants stadium has the second most seating capacity
Both are correct depending upon the interpretation. If you are referring to the collective years, than the first example is correct. If you are referring to a specific year, then the second, possessive example, is correct.
Yes, capacity refers to the maximum amount of data that can be transmitted by a medium within a specific time frame, usually measured in bits per second (bps) or bytes per second. It determines how much information can be communicated effectively over the medium.
It is grammatically correct to spell out the word for numbers of ten and less, hence, "second century B.C." is correct. Also, Second Century BCE is correct.
The viscosity of glycerol at zero degrees Celsius is approximately 1.41 Pa·s (pascal-second).
The sea level has nothing to do with the speed of sound. It's the temperature that matters. At 20° Celsius the speed of sound c = 343 m/s. At 20° Celsius the speed of sound is c = 13 503.937 inches/second.
at 0 degrees Celsius sound travells 330 metres per second at 20 degrees Celsius sound travells 340 metres per second at 30 degrees Celsius sound travells 350 metres per second in water sound travells 1400 meters per second through wood sound travells 4500 metres per second through steel sound travells 5000 metres per second
Correct, the word you denotes the second person.