Answer:
yes they did and they dont fund pe or athletics as much as they used to
Explanation:
The Soviet Invasion of Afghanistan and the U.S. Response, 1978–1980. At the end of December 1979, the Soviet Union sent thousands of troops into Afghanistan and immediately assumed complete military and political control of Kabul and large portions of the country.
Answer:
Cuase it will be easy to eat and paly
Explanation:
Answer:
Roselle was able to help Michael because she was a guide dog and know-how to take Michael in and out of places, besides Michael kept calmed all the time so Roselle could focus on the exit.
Explanation:
On 9/11 Michael was working as in any other normal day in the office, and when he felt that the building was moving he thought it was an earthquake and because his sense of self-control Roselle was able to guide him and his co-worker to the exit without any harm, them both became celebrities. Michael even wrote a book about the event.
The options to the question asked are listed below
A)The voltage across both the resistor and the capacitor is zero.
B)The voltage across the resistor is zero, and the voltage across the capacitor is equal to the terminal voltage of the battery.
C)The voltage across both the resistor and the capacitor is equal to the terminal voltage of the battery.
D)The voltage across the resistor is equal to the terminal voltage of the battery, and the voltage across the capacitor is zero.
E)The voltage across both the resistor and the capacitor is equal to one-half of the terminal voltage of the battery.
Answer:
D. The voltage across the resistor is equal to the terminal voltage of the battery, and the voltage across the capacitor is zero.
Explanation:
As soon as the switch is closed, the capacitor starts to charge through the resistor. At the moment the switch is closed, the voltage across the resistor equals the terminal voltage and the voltage across the capacitor equals zero. As the time, t increases, the capacitor begins to get charged and the voltage across it increases based on the formula
Vc=Vt (1-e^(-t/Rc)) where Vt is the terminal voltage and Vc is the voltage across the capacitor.