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Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||the terminal"s electrical state is not effected by the incomplete circuit. | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||There is still a voltage is the different terminals | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||The terminal is still connected to an electrical state of the battery | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||it always has the same voltage due to a chemical reaction inside of it | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||a battery is always in the same electrical state. it has a chemical reaction inside of it. | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because the battery has its own electrical state within given by the lead | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||the battery has its own chemical reaction | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because terminals are seperate | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||not connected | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||battery uses charge | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because a batter will always have a voltage even if it is 0 | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because a battery will always have a voltage even if it is 0 | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because a battery always has a chemical reaction, positive or negative | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because a chemical reaction inside the battery keeps the positive and negative terminals at different electrical states at all times. | correct |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||A battery will always have a voltage because the electrical states of the positive and negative terminals are always different. | irrelevant |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||A chemical reaction inside the battery makes the electrical states of the positive and negative terminals different at all times. | correct |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||The two terminals of a battery will always have different electrical states due to a chemical reaction inside the battery | correct |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||The voltage does not change. | irrelevant |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because it will still be connected to one of the terminals | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because the gap creates a difference in electrical states | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||the voltage of a battery is the result of chemical reactions within the battery | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because it has one regardless of the circuit | irrelevant |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||battery always has voltage | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because there is a difference between the electrical states of the two terminals. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because there is still a difference in electrical states. One side could have a positive connection and the other could have a negative connection | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because the terminals are not in a closed path, so you are giving the voltage of the battery itself | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because the battery always has a voltage unless it"s dead | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because it has two electrial states within itself. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because they aren"t connected | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||battery will always have a voltage | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||There will be a difference in measured electrical states | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because | non_domain |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||a gap in the circuit does not affect the voltage of the battery. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||An incomplete circuit does not affect voltage. | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||it can be 0 | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||a battery always has voltage unless it is damaged | irrelevant |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||circuit has nothing to do with the batteries voltage | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Well, it will have a voltage of zero, if that"s what you are asking. | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||The battery"s voltage comes from a chemical reaction that takes place within the battery itself. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because the electrical states between the two battery terminals will be different no matter what | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||there is a gap | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||beacause the two terminals still have an electrical state | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||the battery always has a voltage because there is a positive terminal and there is a negative terminal. | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because it is measuring the difference in electrical states between two terminals. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because the battery contains chemicals that differe in electrical states. | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||the voltage stays the same within the battery | contradictory |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||I don"t know | non_domain |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||Because the two terminals will always have different electrical states. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because voltage is the difference in electrical states between two terminals. | partially_correct_incomplete |
Why?||A battery uses a chemical reaction to maintain different electrical states at the terminals||because the battery has its own chemical reacion between the positive and negative tterminals it contains | partially_correct_incomplete |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because bulb b and c were still in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulbs b and c were contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb B and C were still contained in a closed path with tthe battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulbs b and c were in a closed paty with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because bulbs b and c are on a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because bulbs b and c are in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulbs B and C are still contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||switch x is not in the same path as bulbs b and c. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||switch x is not in the same path of bulbs b and c. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Because bulb B and C were contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because bulbs b and c were still contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulbs b and c were in a closed path with a battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb X was still contained in a closed path withy the batteyr | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb B and C was stilled contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulb b and bulb c were still contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb A and bulb C are in a closed path with the battery. | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb B and bulb C are in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||switch X does not effect bulbs B and C | partially_correct_incomplete |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulbs b and c were still contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||they were in a closed path with a battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulbs b and c and switch y are contained in a closed path with a battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb B and C were in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulb b and c are on a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||tell answer | non_domain |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb B and C were contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulb B and C were in a closed path with a battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulb c was still contained in a closed path with the battery. bulb b was still contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulbs b and c were in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulbs b and C were still on a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulb b and c were still contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||there was a closed path with the battery and bulbs b and c | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because they were in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because bulbs b and c were contained in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Because bulbs B and C were contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulbs B and C are still contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||They were still contained in the path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||they were futher away from the connection | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||both bulbs were still on a closed path connected to the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulbs b and c were still contained on a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||B and C were still contained in a closed circuit with the battery | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||They were contained in a closed path | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||Bulbs B and C were still contained in a closed path with the battery. | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||because they are still in a closed circuit | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||bulb b and bulb c were in a closed circuit with the battery | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||no gaps | partially_correct_incomplete |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||they were in a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||they were contained within a closed path with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||yes | contradictory |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||they were still on closed paths with the battery | correct |
When switch X was open and switch Y was closed, why were bulbs B and C on?||Bulb B and Bulb C were still contained in the same closed path with the battery.||iBulbs ba nd C were stil contained in a closed path with the battery | correct |