The Role of Charge in Chemistry

The Role of Charge in Chemistry
Sticky Tape Post Lab The Role of Charge in Chemistry

Charge on a Macroscopic Scale
Opposite charges attract each other. Similar charges repel each other. Neutral objects are attracted to all charged objects, but exert no force on other neutral objects.

Charge on the Particle Scale
All particles contain both positive and negative charges that normally cancel each other out. An object may become charged when some of its positive or negative charges are transferred to another object.

J.J. Thomson conducted experiments in the 1890’s with cathode rays to demonstrate which charges are able to be transferred.

Some interesting facts about chocolate chips . . . Positively-charged dough attract negative chips. Some dough is better at attracting chips than other dough. Chips can move from one bowl to another due to these differences in attraction. **Since chips repel each other, the number of chips that can fit in dough is limited**

We’ll call this the chocolate chip model The positive cores are represented by scoops of dough The negative charges are represented by chocolate chips. Positive Core Negative Charges

Some interesting facts about dough . . . ChocoChips (-) fall out of some dough Some dough can attract extra ChocoChips. A ball of dough with extra chips (-) has a negative charge. ChocoChips (-) can move around in one ball of dough or be transferred between balls of dough. ChocoChips (-) are repelled by other ChocoChips (-)

Cookies vs. Tape Normal dough has the perfect # of ChocoChips to counteract the positive dough. Some dough looses chips and becomes “chip-lite” (+) Some dough gets extra chips and becomes “chip-heavy” (-)

What are we really talking about? Thomson’s model proposed that what we once thought of as the smallest pieces of matter are actually composed of two parts: Large, massive, positively-charged core. Tiny negatively-charged particles spread throughout the positive core = called electrons. The positive core is immobile, the negative electrons can move from one particle to another.

Charge is not a substance. Charge is a property of particles (cores and electrons) that determines the strength of their electrical interactions. Charge plays the role of mass in gravitational interactions.

Charges in the Sticky Tape
Consider which tape was negatively-charged after they were separated. The bottom tape was negative, so the smooth side of the tape must have a stronger attraction to the negative electrons.

The particle-level transfer of electrons results in an imbalance of charge in both pieces of tape. The positive cores remain the same, the top piece now has an excess of (+) charge, the bottom piece has an excess of (-) charge. top(+) bottom (-) Before Adhesion In Contact Separated

Bottom tape has same + core but extra – electrons. Each bottom tape is now NEGATIVE! Top tape has same + core but fewer – electrons. Each top tape is now POSTIVE! top(+) bottom (-) Before Adhesion In Contact Separated

Charge and Electrical Conductivity
What type of substances conduct electricity? Metals Some Solutions Electrical conductivity is the result of electrons moving from one core to another when subjected to an external electrical field.

Charge and Electrical Conductivity
What is it about metals that allows electrons to move from one core to another? Metal’s cores are not strong attractors of negative charge. The energy required to move an electron from one metallic core to another is relatively low compared to that of a nonmetal.

Part II Sticky Tape Post-Lab

Interactions Between Charged and Neutral Objects
Both the top and bottom tape attracted the foil and paper. The tape-foil interaction was stronger than the tape-paper interaction. What is different about the behavior of the negative charges in the two substances? Charge in a neutral substance is evenly-distributed, this is true for both the foil and the paper.

In the foil, the negative charges can move from one core to another. We say the charge is delocalized. When a (+) object is placed close to the foil, the negative charges move closer to the object and the electrons are no longer evenly distributed.

In the paper, the negative charges are bound to their positive cores. The paper is still polarized as the negative charges move closer to the (+) charge. The polarization is less pronounced than in the foil because the electron distribution is not as asymmetrical.

Definitions Label periodic table.
Metals – The positive core of metals do not have a strong attraction to the negative electrons. Electrons tend to leave metals so the metals become positive. (+) Nonmetals – The positive core of nonmetals have a strong attraction to the negative electrons. Extra electrons get pulled towards the nonmentals so they become negative. (-) Label periodic table.

Electrical conductors are more-readily polarized than nonconductors because their electrons can move from one core to another. Conductor Nonconductor

Sketch the charged particle diagrams for: The bottom tape held in between a piece of foil and a piece of paper. The top tape held in between a piece of foil and the bottom tape. A piece of foil held in between the bottom tape and a piece of paper. A piece of foil held between the top tape and the bottom tape.

Charges in Compounds Electrical interactions resulting from charged particles result in the formation of compounds. Different types of particles have different cores, and therefore different abilities to attract negative electrons. Differences in core ability to attract electrons results in different types of compound formation and different compound properties.

The Role of Charge in Chemistry

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