Chemistry - CBSE Academic
... Elevation in boiling point is a colligative property which depends on the number of particles. NaCl is an ionic compound which dissociates in solution to give more number of particles whereas sugar is made up of molecules and thus does not dissociate. ...
... Elevation in boiling point is a colligative property which depends on the number of particles. NaCl is an ionic compound which dissociates in solution to give more number of particles whereas sugar is made up of molecules and thus does not dissociate. ...
Example 17 Use current division to determine the current i through
... So we can use a single resistor to replace the two resistors. The two 10 kΩ resistors have the same pair of nodes, hence they are in parallel. To combine the parallel resistors, we can take the reciprocal of the first resistance and take the reciprocal of the second one and add together, and then ta ...
... So we can use a single resistor to replace the two resistors. The two 10 kΩ resistors have the same pair of nodes, hence they are in parallel. To combine the parallel resistors, we can take the reciprocal of the first resistance and take the reciprocal of the second one and add together, and then ta ...
1. All the questions are compulsory. 2. Q. N
... Elevation in boiling point is a colligative property which depends on the number of particles. NaCl is an ionic compound which dissociates in solution to give more number of particles whereas sugar is made up of molecules and thus does not dissociate. ...
... Elevation in boiling point is a colligative property which depends on the number of particles. NaCl is an ionic compound which dissociates in solution to give more number of particles whereas sugar is made up of molecules and thus does not dissociate. ...
Chapter 6 Current and Resistance
... where J is the current density (the SI unit of current density are A/m 2 ). If q is the charge of each carrier, and n is the number of charge carriers per unit volume, the total amount of charge in this section is then ∆Q = q(nA ∆x) . Suppose that the charge carriers move with a speed vd ; then the ...
... where J is the current density (the SI unit of current density are A/m 2 ). If q is the charge of each carrier, and n is the number of charge carriers per unit volume, the total amount of charge in this section is then ∆Q = q(nA ∆x) . Suppose that the charge carriers move with a speed vd ; then the ...
summer fun - West Windsor-Plainsboro Regional School District
... balance equations. For the AP Chemistry exam, all equations must be written in net ionic form and you must be able to recognize types of reactions and then predict products. We will be writing net ionic equations all year and our beginning lab work will involve recognizing types of reactions and pre ...
... balance equations. For the AP Chemistry exam, all equations must be written in net ionic form and you must be able to recognize types of reactions and then predict products. We will be writing net ionic equations all year and our beginning lab work will involve recognizing types of reactions and pre ...
lecture17
... Example: The electric current of 0.5 A is flowing through the electric conductor. a) What electric charge is passing through the conductor during each second? b) What electric charge will pass through the conductor during 1 minute? ...
... Example: The electric current of 0.5 A is flowing through the electric conductor. a) What electric charge is passing through the conductor during each second? b) What electric charge will pass through the conductor during 1 minute? ...
View File - UET Taxila
... the same potential, i.e. potential is constant everywhere inside a conductor Finally, since one of the points can be arbitrarily close to the surface of the conductor, the electric potential is constant everywhere inside a conductor and equal to its value at the surface! Note that the potential insi ...
... the same potential, i.e. potential is constant everywhere inside a conductor Finally, since one of the points can be arbitrarily close to the surface of the conductor, the electric potential is constant everywhere inside a conductor and equal to its value at the surface! Note that the potential insi ...
In saturation mode, how is it possible that current is flowing from n
... the base. In addition e- from the emitter transit through the base, some recombine there, most go on into the collector. There is more than 1 thing happening here. The b-e & the b-c junctions are both forward biased for the saturated state. In cutoff or active state, the b-c junction is reverse bias ...
... the base. In addition e- from the emitter transit through the base, some recombine there, most go on into the collector. There is more than 1 thing happening here. The b-e & the b-c junctions are both forward biased for the saturated state. In cutoff or active state, the b-c junction is reverse bias ...
Document
... the same potential, i.e. potential is constant everywhere inside a conductor Finally, since one of the points can be arbitrarily close to the surface of the conductor, the electric potential is constant everywhere inside a conductor and equal to its value at the surface! Note that the potential insi ...
... the same potential, i.e. potential is constant everywhere inside a conductor Finally, since one of the points can be arbitrarily close to the surface of the conductor, the electric potential is constant everywhere inside a conductor and equal to its value at the surface! Note that the potential insi ...
EC8011 40V Gate Pulse Modulator - E-CMOS
... switch control block is enabled when VDPM exceeds VREF and then P1 and P2 are controlled by VFLK and CD. There are three different modes of operation (see the Typical Application Circuit and Timing Diagram). Activate the Mode A by connecting CD to 5V. When VFLK is logic high, P1 turns on and P2 turn ...
... switch control block is enabled when VDPM exceeds VREF and then P1 and P2 are controlled by VFLK and CD. There are three different modes of operation (see the Typical Application Circuit and Timing Diagram). Activate the Mode A by connecting CD to 5V. When VFLK is logic high, P1 turns on and P2 turn ...
Magnetic forces on moving charges – More than just a
... Magnetic forces on moving charges – More than just a nice theory! Back in 1820, Hans Christian Oersted discovered that as well as producing a magnetic field, an electric current experiences a force when placed in a magnetic field. That force is given by the expression F = IlB. We now regard a curren ...
... Magnetic forces on moving charges – More than just a nice theory! Back in 1820, Hans Christian Oersted discovered that as well as producing a magnetic field, an electric current experiences a force when placed in a magnetic field. That force is given by the expression F = IlB. We now regard a curren ...
CHEM_S1CourseReview_2011
... 10. Which diagram correctly depicts the trend in atomic radius? ________ 11. Elements in the same group have similar ______________. They behave similarly because they have the same number of ________________. 12. Metals are located on the ____________ side of the periodic table and nonmetals are on ...
... 10. Which diagram correctly depicts the trend in atomic radius? ________ 11. Elements in the same group have similar ______________. They behave similarly because they have the same number of ________________. 12. Metals are located on the ____________ side of the periodic table and nonmetals are on ...
Bonding and Structure - Lesmahagow High School
... water or when molten as the ions are free to move. Electrolysis of an ionic solution or melt causes a chemical change at the electrodes. They do not conduct when solid as the ions are ‘locked in the lattice and cannot move to carry the current. ...
... water or when molten as the ions are free to move. Electrolysis of an ionic solution or melt causes a chemical change at the electrodes. They do not conduct when solid as the ions are ‘locked in the lattice and cannot move to carry the current. ...
Nanofluidic circuitry
Nanofluidic circuitry is a nanotechnology aiming for control of fluids in nanometer scale. Due to the effect of an electrical double layer within the fluid channel, the behavior of nanofluid is observed to be significantly different compared with its microfluidic counterparts. Its typical characteristic dimensions fall within the range of 1–100 nm. At least one dimension of the structure is in nanoscopic scale. Phenomena of fluids in nano-scale structure are discovered to be of different properties in electrochemistry and fluid dynamics.