instructions;

In order to understand each of these speeds and why they are all different and yet physically meaningful, we need to understand the basics of electric currents. Electric currents in metal wires are formed by free electrons that are moving. In the context of typical electric currents in metal wires, free electrons can be thought of as little balls bouncing around in the grid of fixed, heavy atoms that make up the metal wire. Electrons are really quantum entities, but the more accurate quantum picture is not necessary in this explanation. (When you add in quantum effects, the individual electron velocity becomes the "Fermi velocity".) The non-free electrons, or valence electrons, are bound too tightly to atoms to contribute to the electric current and so can be ignored in this picture. Each free electron in the metal wire is constantly flying in a straight line under its own momentum, colliding with an atom, changing direction because of the collision, and continuing on in a straight line again until the next collision. If a metal wire is left to itself, the free electrons inside constantly fly about and collide into atoms in a random fashion. Macroscopically, we call the random motion of small particles "heat". The actual speed of an individual electron is the amount of nanometers per second that an electron travels while going in a straight line between collisions. A wire left to itself carries no electric signal, so the individual electron velocity of the randomly moving electrons is just a description of the heat in the wire and not the electric current.

Now, if you connect the wire to a battery, you have applied an external electric field to the wire. The electric field points in one direction down the length of the wire. The free electrons in the wire feel a force from this electric field and speed up in the direction of the field (in the opposite direction, actually, because electrons are negatively charged). The electrons continue to collide with atoms, which still causes them to bounce all around in different directions. But on top of this random thermal motion, they now have a net ordered movement in the direction opposite of the electric field. The electric current in the wire consists of the ordered portion of the electrons' motion, whereas the random portion of the motion still just constitutes the heat in the wire. An applied electric field (such as from connecting a battery) therefore causes an electric current to flow down the wire. The average speed at which the electrons move down a wire is what we call the "drift velocity".

quetsions

1.reason accordingly the zeal for the initiation of the principle of the DUE DILIGENCEin managerial accounting

2.explain another reason why the due diligence may be a resourceful match for the synergies betweentwo companies which are in conflict

3.due to the communication niches and the horizontal information; explain how to initiate the process ofMAKING DUE DILIGENCE WORK for staff of the managerial accounting

4.outline the critical confirmations from the establishment of the information of the due diligence in managerial accounting

5.what is the pro-active side of the due diligence feature of the staff thatrelate to the in depth expectations n managerial accounting?

6.what decisions guide Future Earnings as the synergetic effect of the bargaining dilutions of the earning per share by the managerial accountants?

7.how does the market value serve the same purpose as the stated above parameter ?

8.ensure you explain the complex task of thepure financial merger in regard to the cash flows handledby the managerial accountants

9.dictate and explain in thorough format the ANTI-TAKEOVER DEFENSESand their relevance to the companies concerned about takeovers in managerial accounting

10.how does the poison pill phenomenon help mitigate the above stated problem?