From this picture, we can learn many things. One of them is: You have nice toes on your left foot.
#10). That's 'electric current'.
#11). On the left: Only one possible path for current. That's a series circuit. On the right: Two (or more) possible paths for current. That's a parallel circuit.
#12). If lamp-A burns out, lamp-B will go out too. All of the current for both lamps has to flow through both of them, because that's the only path in the circuit. If one lamp burns a hole in itself, then current can't flow through the circuit any more, and everything goes out. That's how a series circuit behaves.
If lamp-C burns out, lamp-D continues to shine. Even though current can't flow through lamp-C any more, it can ctill flow through lamp-D, so lamp-D doesn't care. It keeps shining.
#13). No, they don't have to. If there's ENOUGH charge built up on them, then the attraction between the charges is strong enough to jump across from one object to the other one. This is exactly what happens when ENOUGH charge builds up on the bottom of a cloud ... the charge can jump across the whole open space between the cloud and the ground. We call that "lightning".
#14). I'm not sure I can explain this with things you've already learned. Try this: Electrons have to do some work to flow through a wire. That's why we need a battery to make current flow in a circuit. The battery supplies energy for the electrons to use on their trip through the wire. The electrons give up some of their energy as they flow through the wire, and it comes out of the wire in the form of heat energy. (If there was ENOUGH current flowing through the wire, then the wire would get so hot that it would glow. This is exactly what's going on in a light bulb.)
#15). Look back at the picture of the parallel circuit ... the one with lamps C and D.
Let's say the student built the circuit with only lamp-C in it, and then he wanted to increase the current in the circuit. There are two ways he could do that:
. . . . . Put in a battery with more voltage.
. . . . . Add the other lamp ... lamp-D. Now that the current has two possible paths, more current will come out of the battery, and some of it will follow each path.
#16). I talked about this earlier. The 'filament' is the little thin wire inside the light bulb. It's made to get very hot and start to glow when current flows through it. It can do that for a long time without burning up, because all the air has been pulled out of the bulb. But sooner or later, that little skinny wire is going to break, and then, there's no path for current to flow through the bulb. We call it a "burned out" bulb.
#17). If the resistance in the circuit changes (and the voltage of the battery stays the same), then the current in the circuit decreases.
#18). When you rub the balloon against your hair, electrons come off of one surface and jump onto the other one ... I can never remember whether the electrons jump to the balloon or to the hair. But whatever direction it is, the balloon becomes charged ... either it has too many electrons (negative charge) or else it has not enough electrons (positive charge). When you put the balloon up against the wall, some charges in the wall move either toward or away from the balloon. THEN, you have two charged objects, attracting each other, so they stick, until some charges leak away onto air molecules that pass by.
#19). Whenever we see electrical stuff going on, it's always electrons that are moving.
You've learned how an atom is built ... electrons in a cloud around the outside, and the protons in the nucleus, deep deep deep deep inside the atom. The nucleus is kind of protected from the outside world by being inside the cloud of electrons. Nothing leaves the nucleus unless it's in a radioactive substance, or else it's being shot with high-energy particles in an "atom smasher" in a Physics laboratory. In the everyday world, it's only electrons flowing through electrical things, jumping from clouds to the ground in lightning, or jumping between your finger and the doorknob after you walk across the carpet.
#20).
Again, this is an awful lot of work for 5 points, and you don't learn very much when somebody else gives you whole answers. So I'm going to stop here, and leave the rest to you or to another Brainly contributor.
The thermal balance refers to when there is no heat transfer between the bodies and their surroundings i.e. the bodies and the environment are at the same temperature.
Suppose two bodies of different masses and different materials, each one of them is at a temperature of 25(° C), which is the same temperature as the temperature of the environment, if these two bodies are close to each other, there is also heat transfer as they are at the same temperature, in the absence of any type of energy that enter or exit in these bodies, the amount of internal energy will be equal in both bodies.
Note: when the internal energy of one of these bodies is increased, heat transfer will happen, always looking for the thermal balance.
2: It's not just the capillary action, but the pull from transpiration (the evaporation of water from the tree) that is used to pull water up from the roots.
<span>The second question needs context. Strong bonds alone won't cause tension. I don't see how adhesion is different. High vapour pressure could do it, but it's the difference in pressures that'd cause tension (and the resistance of that pressure by the surface). So, a low and high pressure would be needed. Poorly worded question :( </span>
<span>1: "Adhesion is the tendency of certain dissimilar molecules to cling together due to attractive forces." [1] </span>
<span>3: The other three answere would not work. Think of a boat. </span>
<span>3: If you push gas, it will be compressed(get smaller). If you push liquid it will push something else. Thus, liquids are good for transferring force. This is a hydraulic system.</span>
force by the helicopter
force of gravity