Want this question answered?
Neither charge nor volts is a conductor. These are terms for electricity, the movement of electrons along a conductor. A conductor is the medium that carries the charge and a volt is the amount of electrical 'pressure' which is being carried. A conductor is generally a wire of other copper (sometimes carbon, sometimes aluminum or some other metal) but could be any other material. could be anything resistor, capacitor, ac/dc converter, microchip etc. they all conduct electricity by the method above, altering the properties of the energy.
A semiconductor material forms a crystal structure where all the valence electrons "participate" in forming the lattice. There are neither "extra" nor "missing" electrons in the structure. If we dope the semiconductor with a "P-type" material, this sets the stage for the creation of a "hole" in that matrix. The P-type material will have one less valence electron than our semiconductor material. And when that P-type atom becomes part of the crystal matrix, it lacks that one electron to make the matrix "complete" or "uniform" as regards the electrons. That creates the hole in the matrix. When that P-type material is formed up against N-type material (which has an "extra" electron in its matrix), that extra electron will leave the N-type material and migrate to the P-type material to fill that hole. This sets up a condition where charges have shifted, and it creates a difference of potential (voltage) across the junction (owing to the shift of the electrons).
It depends - logically - on the caliber of the bullet, and the thickness of the pine. A deer rifle bullet will penetrate a 2x4 with no difficulty, and may or may not penetrate a 4x4. A .22 will penetrate neither, a .50 machine gun bullet will penetrate an 8x8. Loosely speaking, I would not consider pine to be a bulletproof material.
review how you are spelling this, neither is a word.
Reactance is -1/2 pi F C so a 25 uF capacitor at 400 Hz would have a reactance of about -15.9 ohms. The negative sign indicates that capacitive reactance is leading, with current leading voltage.AnswerI would take issue with the previous answer that capacitive reactance is expressed as a negative value, or that it is 'leading'. Reactance is not a vector quantity, so it neither leads nor lags anything. In a (theoretically) purely capacitive circuit, it is the load current that leads the supply voltage. However, when using complex notation, capacitive reactance is expressed as -j 15.9 ohms, where 'j' is called an 'operator' -but even this does not mean that the reactance is 'leading', as it defines reactance in terms of a current phasor -in other words, the '-j' refers to the relative position of current to voltage, not reactance to impedance.
Wind is not considered as a material, so neither is it a raw material.
Yes. Since there is no phjysical material in the space between Sun and Earth, neither conduction nor convection is an option.
Usually it is neither, but it can be either.
Neither float (which it would if the material were less dense) nor sink (which it would if it were more dense). It will "hover" wherever you place it in the liquid, like a scuba diver who has neither negative nor positive buoyancy.
Because it's neither solid or liquid.
gas
Neither. Flame is a mixture of air and partially burned material.
Gas.
Neither, your index finger should be just touching the outer edge of your right eyebrow.
typically, you don't attach capacitors to ceiling fans ( 120V or 240V ). A capacitor would only be used for one of two reasons. 1. to reduce the noise on the AC in your home or 2. to reduce the spikes to your fan... neither of these make any sense.
Neither "O" nor "-" typically mean "on" in English. "On" is the standard preposition to indicate something is located on top of or physically touching something else.
Actually, neither d.c. nor a.c. current passes through a capacitor. A.C. current 'appears' to flow through a capacitor but, in reality, it is only flowing through the connecting circuit while what is known as a 'displacement current' (actually, a distortion of the atoms' shells rather than a conduction current) occurs within the dielectric separating the capacitor's plates. D.C. current is 'blocked' by a capacitor because, when the capacitor is fully charged, the potential difference appearing across its plates is equal and opposite that of the supply. With no net potential difference in the circuit, no current can flow.