Seeming that I an doing the same essay as I type this, war resistance was more effective than rebellion. Because it was on a larger scale than rebellion
Resistance to slavery could be as effective as rebellion in certain contexts. While rebellion often involved direct resistance and armed struggle against slaveholders, resistance through acts of everyday defiance, such as sabotage, evasion, and cultural preservation, could also challenge and undermine the institution of slavery. Both forms of resistance contributed to eroding the power dynamics of slavery and played a significant role in emancipation movements.
Slavery was less successful in the north due to the fact that the north was more of a merchant society than the south was. Slavery was more "necessary" in the south because of the vast amount of farmland that was present in the south. The north however, relied more on trading/
1. Grain production 2. Less slavery 3. Quakers 4. Slavery 5. Cattle
Radical abolitionist John Brown and his sons already had massacred pro -slavery people in Kansas. He escaped the law and then was funded by rich New England abolitionists to incite a slave riot. He took over a Federal arsenal and with the weapons tried to incite a slave revolution. No slaves joined him and he was hanged for treason.
No. Slavery also existed in the Northern colonies before and after the American Revolution. It became less common by 1790 in the north.
the highly trained infantryman. any weapon in an untrained Soldiers hands are less effective
What do you mean? In a parallel circuit, the combined (or effective) resistance is less than any individual resistance.
The effective resistance of the capacitor reduces the ripple current through the capacitor making it less effective in its function of smoothing the voltage. But if the capacitor filter is fed by a transformer and diodes, the resistance of the transformer exceeds that of the capacitor.
When connected in series, the overall effective resistance of a bunch of individual resistors is the sum of the individual resistances. It's always more than the resistance of any individual. When connected in parallel, the reciprocal of the overall resistance of a bunch of individual resistors is the sum of the reciprocals of the individual resistances. It's always less than the resistance of any individual. When two resistors are connected in parallel, the overall effective resistance of the pair is (the product of the two individual resistances) divided by (the sum of the two individual resistances). It's always less than the smaller individual resistance.
There is no such thing as a "parallel series". The total effective resistance of many resistors in series is the sum of the individual resistances. It's more than the greatest individual. The total effective resistance of many resistors in parallel is the reciprocal of the sum of the individual resistances' reciprocals. It's less than the smallest individual.
Well bacteria (which cause sickness) have developed a resistance to medication since people use it a lot.
Drug resistance in bacteria can be harmful to humans because it can result in less effective treatments for infections. Higher doses may be needed to treat infections, and so treatment may have more risks. In some cases, antibiotics may no longer be effective at all.
When many resistances are connected in series, the equivalent resistance is greater than the greatest single resistance. When many resistances are connected in parallel, the equivalent resistance is less than the smallest single resistance.
Short wire has less resistance Long wire has more resistance Thick wire has less resistance Thin wire has more resistance
Yes. When resistors are connected in "parallel" (all the left ends connected together and all the right ends connected together) the effective resistance is always less then the smallest resistor in the group. For example If you connected a 2 ohm in parallel with a 4 ohm the effective resistance is 1.33 ohm. To your question; if you connect N equal resistors R in parallel the effective resistance would be R/N . The formula for calculating effective resistance R of a group R1, R2, R3, ... in parallel is: 1/R = 1/R1 + 1/R2 + 1/R3 + .... Note; write the right side as a single fraction by getting a common denomenator then invert to get R.
You can, but you may damage your amp. If you wire them in parallel (both wires from each connected to the amp) then you will have an effective resistance less than 2 ohms. If you wire them in series then you will have an effective resistance of 6 ohms. Resistance that is too low draws more power than the output is rated for. Resistance that is too high reduces the volume and may distort the sound.
antibiotics make these medicines less effective?
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