Static Electricity Reading

Descripción

Test sobre Static Electricity Reading, creado por Wallace Mason el 15/04/2019.
Wallace Mason
Test por Wallace Mason, actualizado hace más de 1 año
Wallace Mason
Creado por Wallace Mason hace más de 5 años
901
0

Resumen del Recurso

Pregunta 1

Pregunta
Charge and static All matter has [blank_start]charge[blank_end], in the same way that all matter has mass. Atoms have [blank_start]no[blank_end] overall charge – they are [blank_start]neutral[blank_end]. This is because atoms contain equal numbers of [blank_start]protons[blank_end] and [blank_start]electrons[blank_end]. Electrons carry a [blank_start]negative[blank_end] electric charge and protons carry a [blank_start]positive[blank_end] electric charge. Static [blank_start]Electrons[blank_end] can be made to move from one object to another. However, [blank_start]protons[blank_end] do not move because they are tightly bound in the nuclei of atoms. For example, when a plastic rod is rubbed with a duster, [blank_start]electrons[blank_end] are transferred from one material to the other. The material that gains electrons becomes [blank_start]negatively[blank_end] charged. The material that loses electrons becomes [blank_start]positively[blank_end] charged. Static charge occurs when electrons build up on an object. Static charge: can only build up on objects which are [blank_start]insulators[blank_end], eg plastic or wood cannot build up on objects that act as [blank_start]conductors[blank_end], eg metals Conductors allow the electrons to flow away, forming an [blank_start]electric current[blank_end]. When a static charge on an object is [blank_start]discharged[blank_end], an electric current flows through the air. This can cause [blank_start]sparks[blank_end]. [blank_start]Lightning[blank_end] is an example of a large amount of static charge being discharged.
Respuesta
  • charge
  • no
  • neutral
  • protons
  • electrons
  • negative
  • positive
  • Electrons
  • protons
  • electrons
  • negatively
  • positively
  • insulators
  • conductors
  • electric current
  • discharged
  • sparks
  • Lightning

Pregunta 2

Pregunta
Opposite (unlike) charges [blank_start]attract[blank_end] one another. Like charges [blank_start]repel[blank_end] one another. Demonstrating charge The only way to tell if an object is charged is to see if it [blank_start]repels[blank_end] another charged object. This is because a charged object can attract an [blank_start]uncharged[blank_end] insulator. For example, a [blank_start]negatively[blank_end] charged plastic object such as a comb or ruler repels electrons in a piece of paper. The near side of the paper to the plastic object becomes [blank_start]positively[blank_end] charged, so it is [blank_start]attracted[blank_end] to the plastic object. This is why party balloons [blank_start]attract[blank_end] hair after they have been rubbed on a shirt or jumper.
Respuesta
  • attract
  • repel
  • repels
  • uncharged
  • negatively
  • positively
  • attracted
  • attract

Pregunta 3

Pregunta
Current Current is the [blank_start]rate[blank_end] of [blank_start]flow[blank_end] of [blank_start]charge[blank_end]. In metal wires, electrons move and cause a [blank_start]current[blank_end]. The following conditions are needed for an electric current to flow: 1. a source of potential difference, such as a [blank_start]battery[blank_end], [blank_start]cell[blank_end] or [blank_start]power pack[blank_end] 2. a closed [blank_start]circuit[blank_end], which provides a complete path for the charges to move through Originally, current was defined as the flow of charges from positive to negative. Scientists later discovered that current is actually the flow of electrons, from [blank_start]negative[blank_end] to [blank_start]positive[blank_end]. The original definition is now referred to as ‘conventional current’, to avoid confusion with the newer definition of current. Calculating current To calculate current, use the equation: -charge flow = [blank_start]current[blank_end] × [blank_start]time[blank_end] This is when: 1. charge flow is measured in [blank_start]coulombs[blank_end] (C) 2. current is measured in [blank_start]amperes[blank_end] (amps) (A) 3. time is measured in [blank_start]seconds[blank_end] (s) Each electron in a circuit carries a very small charge but there are many [blank_start]billions[blank_end] of [blank_start]electrons[blank_end] present. Many everyday currents for small household appliances will be measured in milliamps, mA: 1,000 mA = 1 A. Example calculation A current of 60 mA flows through a lamp for half an hour. Calculate the charge transferred. ---- 60 mA = 60 ÷ 1,000 = [blank_start]0.060[blank_end] A ---- 0.5 hours = [blank_start]30[blank_end] minutes ---- 30 × 60 = [blank_start]1,800[blank_end] s charge flow = current × time = 0.060 × 1,800 = [blank_start]108[blank_end] C Question A charge of 5.0 C is transferred through a wire in 20 s. Calculate the current that flows in the wire. Current= Charge Flow/ Time Current= [blank_start]5.0[blank_end] C/ [blank_start]20[blank_end] s Current= [blank_start]0.25[blank_end] A
Respuesta
  • rate
  • flow
  • charge
  • current
  • battery
  • cell
  • power pack
  • circuit
  • negative
  • positive
  • current
  • time
  • coulombs
  • amperes
  • seconds
  • billions
  • electrons
  • 0.060
  • 30
  • 1,800
  • 108
  • 5.0
  • 20
  • 0.25
Mostrar resumen completo Ocultar resumen completo

Similar

Francés - Vocabulario Básico
maya velasquez
Fórmulas Geométricas (Perímetros)
Diego Santos
ÁLGEBRA
JL Cadenas
Aprende cualquier cosa rápidamente con la Técnica Feynman
Ezra Crangle
Historia de la Filosofía
maya velasquez
Esquema del reformismo ilustrado en España
maya velasquez
Práctica sobre el verbo
Kenneth Zapata
Lenguas que influyen en el español
dorydan01
Fechas Clave del Franquismo
ausalgu
COM0 HACER CALENTAMIENTO DE LA MANERA CORRECTA
Sara Moncada
Test de Radicales 2 sencillo
MANUEL LUIS PÉREZ SALAZAR