Quina estructura tenen els metalls?

Els metalls tenen una estructura tridimensional formada per ions positius en files regulars rodejats per electrons delocalitzats.

Per què els metalls condueixen l'electricitat?

Els metalls condueixen l'electricitat gràcies als electrons delocalitzats que es mouen lliurement.

Quines són les propietats físiques comunes als metalls?

Tots els metalls condueixen l'electricitat, són maleables, ductils i brillants.

Què és la sèrie de reactivitat química?

És una classificació dels metalls segons la seva reactivitat creixent, utilitzada per predir les seves reaccions.

Com reaccionen els metalls amb l'aigua?

Els metalls reactius com el sodi reaccionen amb l'aigua freda per formar hidròxid mèssia i gas hidrogen.

Què s'observa quan el sodi reacciona amb aigua?

El sodi flota, es mou per la superfície, produeix bombolles de gas i pot incendiar-se.

Quins metalls no reaccionen amb els àcids?

Els metalls menys reactius com el coure no reaccionen amb els àcids.

Com es pot prevenir la corrosió del ferro?

Mitjançant pintures, lubrificant amb oli, recobriment amb plàstic, galvanitzat i protecció sacrificial.

Quina diferència hi ha entre la reacció dels metalls amb aigua freda i amb vapor?

Els metalls que reaccionen amb aigua freda formen hidròxids, mentre que amb vapor formen òxids.

Què és l'òxid de ferro(III) hidratar?

L'òxid de ferro(III) hidratar és el que coneixem com a rovell del ferro.

IGCSE Chemistry Edexcel Ch 17 Metals - Dr. Hanaa Assil

00:47:03

https://www.youtube.com/watch?v=OwCKa24NN_o

Ringkasan

TLDREl vídeo tracta sobre les propietats físiques i químiques dels metalls, centrant-se en la seva estructura única composta per ions positius i electrons lliures. Es destaca que els metalls són bons conductors elèctrics, brillants, maleables i dúctils. S'expliquen les reaccions dels metalls amb l'oxigen, aigua i àcids, ressaltant la importància de la sèrie de reactivitat per anticipar el comportament dels metalls en aquests processos. També es discuteixen maneres de prevenir la corrosió, com el galvanitzat, que protegeix els metalls mitjançant una capa de zinc que es corroeix en lloc de l'ferro. Alhora, es destaca l'ús de la protecció sacrificial i altres mètodes com recobrir amb plàstic o oli per evitar que el metall s'oxidi.

Takeaways

🌐 Els metalls tenen una estructura tridimensional amb ions positius i electrons lliures.
⚡ Tots els metalls condueixen l'electricitat gràcies als seus electrons delocalitzats.
🔧 Els metalls són maleables i dúctils, permetent diverses aplicacions industrials.
🔥 La reactivitat dels metalls depèn de la seva posició en la sèrie de reactivitat.
🛡️ La corrosió es pot prevenir amb mètodes com la pintura, oli, plàstic o galvanització.
🧪 Els metalls reactius, com el sodi, formen hidròxids i alliberen hidrogen amb aigua.
🔍 La reacció de metalls amb vapor forma òxids en lloc d'hidròxids.
🌊 Els metalls menys reactius no reaccionen amb àcids, com el coure.
🔄 Els metalls més reactius tendeixen a corroejar més ràpidament en presència d'aigua o àcids.
🥇 El rovell del ferro és òxid de ferro(III) hidratat, resultant de la seva oxidació.

Garis waktu

00:00:00 - 00:05:00
En aquest capítol, es discuteixen les propietats físiques i químiques dels metalls. Comença recordant l'estructura dels metalls, destacant que tenen una estructura gegant tridimensional amb ions positius regularment ordenats envoltats per electrons deslocalitzats. Es destaca la capacitat de conduir electricitat, ser maleables i dúctils, a causa dels electrons lliures i la capacitat dels ions per deslizar-los durant l'escalfament o el martelleig.
00:05:00 - 00:10:00
L'explicació continua amb la sèrie de reactivitat química dels metalls, que és una classificació basada en la reactivitat de cadascun. S'explica com els metalls del Grup 1 són més reactius, i es proporcionen exemples com la reactivitat superior del potassi respecte al sodi. També s'inclou com la reactivitat pot deduir-se de la taula periòdica i com els continguts canviants al descendre dins del mateix grup influeixen en la reactivitat.
00:10:00 - 00:15:00
Es presenten les reaccions dels metalls amb oxigen, il·lustrant com la combustió de metalls com el magnesi en oxigen produeix òxids metàl·lics, explicant les observacions com la flama intensa i el sòlid blanc resultant. A més, s'introdueix el concepte d'òxids amfòtics que poden actuar com àcids i bases, exemplificant amb el òxid de magnesi. Se segueix amb mètodes de reacció per descobrir masses en laboratoris.
00:15:00 - 00:20:00
La reacció dels metalls amb aigua es discuteix detalladament, explicant com elements com el liti i el potassi canvien d'aspecte quan es tallen i s'exposen a l'aire, passant de brillant a apagat. També es detalla el procés de la reacció del sodi amb aigua freda que produeix hidrogen i precisions sobre la flotació del sodi degut a la seva baixa densitat. Les característiques presents se solen comprovar en els laboratoris.
00:20:00 - 00:25:00
La reacció dels metalls amb vapor es combina amb la reacció amb aigua freda per introduir una distinció: els metalls més reactius reaccionen amb aigua freda formant hidròxids, mentre que els menys reactius, com el magnesi, reaccionen amb vapor per formar òxids. Es ressalta que els metalls per sota de l'hidrogen no reaccionen amb l’aigua. Aquesta secció juga un paper clau en l’estudi general de les reaccions químiques de metalls.
00:25:00 - 00:30:00
La reacció dels metalls amb àcids es destaca pel fet de formar hidrogen i compostos metàl·lics. S'explica la reactivitat comparativa entre diversos metalls com el magnesi que mostra més bombolles en comparació amb el zinc degut a la seva major reactivitat. Els experiments amb metalls com l’or que no reaccionen es relacionen amb la seva posició per sota de l’hidrogen en la sèrie de reactivitat.
00:30:00 - 00:35:00
S'explica el tipus de reaccions de desplaçament, detallant com un metall més reactiu pot desplaçar un menys reactiu del seu compost. Un exemple donat és la reacció entre zinc i sulfat de coure on el zinc desplaça el coure formant subproductes amb distincions visuals com el canvi de color de blau a incolor. També es ressalten les observacions experimentals d’aquests canvis.
00:35:00 - 00:40:00
El capítol tracta la oxidació dels metalls o la corrosió, amb un enfocament específic en l’òxid ferrós o òxid hidròxid de ferro que s’observa en la ràpida oxidació en presència d’aigua i oxigen. S’introdueixen els mètodes de prevenció com la galvanització i la protecció sacrificial que protegeixen els objectes metàl·lics de la trituració i corrosió per agents atmosfèrics.
00:40:00 - 00:47:03
Finalment, es detallen diferents mètodes per prevenir la corrosió dels metalls, com la galvanització, la qual consisteix en recobrir el ferro amb zinc per evitar l'oxidació, i la protecció sacrificial on un metall més reactiu com el zinc es consumeix abans que el ferro. També s'inclou electroplacatge, que usa corrent elèctric per recobrir els metalls amb diversos elements com la plata.

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Video Tanya Jawab

Quina estructura tenen els metalls?
Els metalls tenen una estructura tridimensional formada per ions positius en files regulars rodejats per electrons delocalitzats.
Per què els metalls condueixen l'electricitat?
Els metalls condueixen l'electricitat gràcies als electrons delocalitzats que es mouen lliurement.
Quines són les propietats físiques comunes als metalls?
Tots els metalls condueixen l'electricitat, són maleables, ductils i brillants.
Què és la sèrie de reactivitat química?
És una classificació dels metalls segons la seva reactivitat creixent, utilitzada per predir les seves reaccions.
Com reaccionen els metalls amb l'aigua?
Els metalls reactius com el sodi reaccionen amb l'aigua freda per formar hidròxid mèssia i gas hidrogen.
Què s'observa quan el sodi reacciona amb aigua?
El sodi flota, es mou per la superfície, produeix bombolles de gas i pot incendiar-se.
Quins metalls no reaccionen amb els àcids?
Els metalls menys reactius com el coure no reaccionen amb els àcids.
Com es pot prevenir la corrosió del ferro?
Mitjançant pintures, lubrificant amb oli, recobriment amb plàstic, galvanitzat i protecció sacrificial.
Quina diferència hi ha entre la reacció dels metalls amb aigua freda i amb vapor?
Els metalls que reaccionen amb aigua freda formen hidròxids, mentre que amb vapor formen òxids.
Què és l'òxid de ferro(III) hidratar?
L'òxid de ferro(III) hidratar és el que coneixem com a rovell del ferro.

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Teks

Gulir Otomatis:

00:00:01
okay hello this is chapter 17
00:00:03
and now we're talking about metals so
00:00:05
we'll be discussing
00:00:06
physical and chemical properties of
00:00:09
metals in order to know that
00:00:11
we have to remind ourselves about the
00:00:13
structure of methods so we've done this
00:00:15
before
00:00:16
but you should remember that when he's
00:00:18
out when you're asked to
00:00:20
explain structure of metals you should
00:00:23
remember to say that metals have a giant
00:00:26
three-dimensional structure in which
00:00:29
regular rows of positive ions are
00:00:31
surrounded by
00:00:32
a sea of three moving electrons so we
00:00:35
said metals basically are solid
00:00:37
so they are made up of regular rows of
00:00:40
something now regular rows of what since
00:00:43
the metals
00:00:44
each atom has one or two or three
00:00:47
electrons in its outermost shell because
00:00:49
we said metals are basically
00:00:51
in group one group two group three and
00:00:53
everything in between
00:00:56
so each atom has one or two or three
00:00:58
electrons in its outermost shell that it
00:01:00
really doesn't want
00:01:01
so these the outermost electrons are
00:01:03
sort of floating around the atom
00:01:06
so the atom is no longer a neutral atom
00:01:09
it is now
00:01:10
a positive eye so these are arranged in
00:01:13
regular rows close
00:01:15
packed like any other solid but they are
00:01:17
also surrounded by
00:01:19
a sea of delocalized electrons or free
00:01:23
moving electrons
00:01:24
remember that sometimes you will be
00:01:26
required to draw
00:01:28
this kind of diagram to show the
00:01:30
structure of
00:01:32
methods okay so
00:01:35
this is a typical question that you
00:01:37
could have about structure of metals so
00:01:39
a question could say
00:01:40
a student draws this label diagram show
00:01:43
the particles in magnesium metal
00:01:45
he makes two mistakes in this diagram
00:01:48
state the two corrections he should make
00:01:50
to his label line so what's wrong with
00:01:52
this diagram
00:01:53
this is a diagram of what of magnesium
00:01:56
metal
00:01:56
now metals we just said are what they
00:01:59
are regular rules of
00:02:01
positive ions not positive and negative
00:02:03
positive negative positive negative
00:02:05
and then they are surrounded by a sea of
00:02:07
delocalized
00:02:09
what delocalized electrons so the two
00:02:13
mistakes in this diagram is that
00:02:15
first of all the ions should be positive
00:02:17
not positive and negative
00:02:19
and the it is surrounded by delocalized
00:02:22
electrons not protons
00:02:26
if we're as physical properties of all
00:02:29
metals you should remember
00:02:30
all metals conduct electricity all
00:02:33
metals are malleable and that time
00:02:35
all metals are shiny these are
00:02:38
properties of all metals there are no
00:02:40
exceptions
00:02:41
so all metals conduct electricity and if
00:02:43
we say
00:02:44
why they conduct electricity that is due
00:02:46
to presence of three moving electrons or
00:02:49
presence of the delocalized
00:02:51
electrons that are free to move
00:02:55
all metals are malleable and doctyle do
00:02:57
you remember what
00:02:58
is meant by malleable end of kind we
00:03:01
said malleable means
00:03:02
we can spread them into sheets like your
00:03:05
aluminium foil that we have at home
00:03:08
end of tile means they can be pulled
00:03:11
into wires like the coupled wires that
00:03:13
we have at home
00:03:14
so all metals are malleable and ductile
00:03:18
why is that
00:03:19
because the layers of positive ions that
00:03:22
are present in the metals can slide
00:03:24
over each other when heated or hammered
00:03:28
and of course all metals are shiny and
00:03:30
if we're asked about the appearance of
00:03:32
the metals we usually say they are
00:03:35
silvery appearance or silvery color
00:03:40
this is another typical question you
00:03:42
could be asked explain
00:03:43
why magnesium metal is malleable and a
00:03:46
good conductor of
00:03:48
electricity so we said it is what it's a
00:03:50
good conductor electricity because it
00:03:52
has
00:03:53
three moving electrons remember
00:03:56
the only one that we say free moving
00:03:58
ions is if i'm talking about an ionic
00:04:01
compound but this here is a metal so it
00:04:04
has
00:04:04
free moving electrons now we said
00:04:07
methods are malleable because
00:04:09
layers of positive ions slide over each
00:04:11
other when heated or hammered
00:04:14
okay so that was the physical properties
00:04:16
of metals now if we talk about the
00:04:18
chemical properties of metals we need to
00:04:21
talk about
00:04:22
chemical reactivity series so the
00:04:24
activity series is
00:04:26
just an arrangement of metals showing
00:04:29
which one is more reactive than which
00:04:32
but even without knowing or memorizing
00:04:35
the chemical reactivity series
00:04:37
you can deduce this from the periodic
00:04:40
table so just looking at the periodic
00:04:42
table you know
00:04:43
that everything in group 1 is more
00:04:45
reactive than group 2
00:04:47
and group 2 is more reactive than group
00:04:49
3 and group 3 is more reactive than
00:04:52
transition models so and within the same
00:04:55
group the one below is more reactive
00:04:57
than the one above
00:04:59
so if i say in group one potassium is
00:05:02
more reactive than sodium so we say
00:05:04
k and then na in group two we have
00:05:08
calcium more reactive than magnesium
00:05:10
because calcium is below mechanism in
00:05:12
the
00:05:13
periodic table then we say calcium and
00:05:15
then magnesium
00:05:16
and then group three has aluminium now
00:05:19
we include in the chemical reactivity
00:05:21
series we include
00:05:22
carbon and carbon monoxide because we
00:05:25
are going to compare the reactivity at
00:05:27
some point
00:05:28
later when we discuss it and then we go
00:05:31
into
00:05:32
the transition methods which is more
00:05:34
reactive than which in the transition
00:05:36
methods
00:05:36
zinc is more reactive than iron more
00:05:38
reactive than tin
00:05:40
remember that the chemical reactivity
00:05:41
series includes the metals that
00:05:43
are normally used in reactions so
00:05:46
some of the the metals in the periodic
00:05:49
table are not
00:05:50
usually used in reactions but the
00:05:53
chemical reactivity series arranges the
00:05:55
reactivity of the ones that we
00:05:57
normally discuss and then we put
00:06:00
hydrogen but
00:06:01
also because we're going to compare the
00:06:03
reactivity of metals to hydrogen at some
00:06:06
point and then below hydrogen we have
00:06:08
the metals that are not very reactive
00:06:11
so we have copper silver and gold these
00:06:14
are
00:06:14
below hydrogen in the reactivity series
00:06:18
so
00:06:18
this is the chemical reactivity series
00:06:21
cana canada
00:06:23
zinc iron tin and then copper silver
00:06:26
gold
00:06:27
if you don't memorize it check in the
00:06:29
periodic table as i told you
00:06:37
okay then we talk about the different
00:06:40
reactions of methods this is what we
00:06:42
mean by chemical properties of matter so
00:06:44
first of all
00:06:45
reaction of metals with oxygen so if i
00:06:48
have a gas
00:06:48
jar like the one in the diagram and i
00:06:52
have a gas jar
00:06:53
spoon and i put the metal in the spoon
00:06:55
lower it
00:06:56
into the gas jar light it allowed to
00:06:59
burn
00:06:59
in oxygen any metal will react with
00:07:03
oxygen to form
00:07:04
its oxide so sodium from sodium oxide
00:07:08
magnesium forms magnesium oxide and of
00:07:11
course we said
00:07:12
the reactivity depends on the
00:07:16
position in the group the one below in
00:07:18
the group
00:07:19
is more reactive than the one above you
00:07:22
have to know
00:07:23
that when we burn magnesium in air or
00:07:26
magnesium and oxygen
00:07:27
first of all what does it give you it
00:07:29
gives magnesium oxide
00:07:31
now what are the observations when i do
00:07:34
this kind of reaction
00:07:37
remember that the observation is when
00:07:39
magnesium burns
00:07:40
it burns with a bright flame or a white
00:07:44
flame and then it forms what it forms
00:07:47
magnesium oxide you should know that
00:07:49
magnesium oxide is
00:07:51
a white solid or white
00:07:54
ash okay um
00:07:57
you should also remember when we talked
00:07:59
about acids and bases we said that
00:08:01
oxides of
00:08:02
metals are usually basic that means if
00:08:05
you dissolve them in water they form an
00:08:07
alkaline solution that contains
00:08:09
hydroxide
00:08:10
ions but we also said that some metals
00:08:13
have
00:08:14
amphoteric oxide you remember the mean
00:08:16
of amphoteric
00:08:17
we said amphoteric oxide is one that can
00:08:20
act
00:08:21
both as an acid so it will react with
00:08:23
the base
00:08:24
or as a base so it will react with acid
00:08:28
and remember from the chapter in acids
00:08:30
and business we said which ones form
00:08:32
amphoteric oxides
00:08:34
aluminium zinc and blood form amphoteric
00:08:37
oxide so aluminum brings in oxygen to
00:08:39
the aluminium oxide
00:08:41
now this aluminum oxide can react with
00:08:43
acid
00:08:44
so in this case it's acting as a base
00:08:46
and that forms aluminium chloride plus
00:08:48
water
00:08:49
so it still forms a salt plus water
00:08:53
or it can act as an acid so it reacts
00:08:55
with a base like sodium hydroxide in
00:08:57
that case the salt is something called
00:09:00
sodium aluminate plus water
00:09:05
this is another question that you might
00:09:06
have so you could be asked
00:09:09
this question a student uses this
00:09:11
apparatus to find the mass of magnesium
00:09:13
oxide
00:09:14
that forms when a strip of magnesium
00:09:16
ribbon is burned in air
00:09:18
so usually this kind of experiments we
00:09:20
put the metal inside the crucible
00:09:22
and we cover it with a lid and we heat
00:09:25
it so the metal turns it
00:09:27
into its oxide and then i can wait or i
00:09:30
weigh the crucible and bleed at the
00:09:31
beginning and then
00:09:32
wait at the end and things like that
00:09:36
now the first question that you have
00:09:37
here says describe the appearance of the
00:09:39
freshly cleaned
00:09:41
magnesium ribbon and the appearance of
00:09:43
the magnesium oxide that forms
00:09:45
magnesium ribbon is a metal we said what
00:09:48
is the appearance of a metal
00:09:51
the appearance of a metal is silvery
00:09:53
okay what was magnesium oxide what was
00:09:56
the appearance of magnesium oxide
00:09:58
you have to remember it's a white solid
00:10:00
or white
00:10:01
ash explain why the student lifts the
00:10:04
lid and quickly replaces it several
00:10:06
times during the experiment
00:10:08
so when we do this kind of experiment
00:10:10
first of all i have to cover it i cannot
00:10:12
leave it open to the air
00:10:13
and then after some time i need to
00:10:16
remove the lid
00:10:17
open the lid and then close it again
00:10:18
open the lid and close it again
00:10:20
so what am i doing why why am i doing
00:10:23
this
00:10:23
i i lift the lid from time to time
00:10:26
remember that the magnesium is trying to
00:10:28
react with what
00:10:30
it's trying to react with oxygen so at
00:10:32
some point i don't want it to run out of
00:10:34
oxygen so i open the lid to allow more
00:10:37
oxygen to react to the magnesium
00:10:39
now why do i have to cover it can't i
00:10:41
just leave it open
00:10:42
no because we said what is formed is
00:10:44
magnesium oxide
00:10:46
and the magnesium oxide is white ash
00:10:49
that can
00:10:50
escape from the crucible so this is to
00:10:52
prevent loss of the product
00:10:54
from the crystal this is another
00:10:58
possible question that you might be
00:10:59
asked
00:11:00
lithium is stored in oil to prevent it
00:11:02
from coming into contact with air and
00:11:04
water remember this
00:11:06
that metals in group 1 are very reactive
00:11:11
when they are exposed to air and
00:11:15
or water they react very quickly so when
00:11:17
i store them
00:11:18
they have to be stored under oil so
00:11:20
things like lithium and sodium and
00:11:23
potassium
00:11:24
if we store them in the lab they have to
00:11:25
be stored under
00:11:27
oil this is to prevent them from
00:11:29
reacting with the
00:11:31
oxygen and water vapor there so the
00:11:33
question says when a piece of lithium is
00:11:35
removed from the oil dried and cut
00:11:38
the exposed surface so remember that
00:11:42
the x i cut the lithium this is a method
00:11:45
in group one and you
00:11:46
remember that methods in group one are
00:11:48
soft metals so you can cut them with a
00:11:51
knife
00:11:52
now once you cut them the the
00:11:55
surface of the metal is just like any
00:11:58
surface of a metal so that is shiny but
00:12:00
if i leave it exposed to the air what
00:12:03
happens
00:12:05
it will react with the oxygen water
00:12:07
vapor in the air and it will change from
00:12:09
shiny to double okay it will not form
00:12:13
bubbles because it's not reacting with
00:12:15
something to be the gas
00:12:16
it will not burst into flames this is
00:12:19
not
00:12:20
uh this is not cesium or
00:12:23
potassium remember that lithium is at
00:12:25
the the top of
00:12:27
group 1 so it is less reactive than
00:12:30
seasonal potassium since you might burst
00:12:32
into flame but lithium will not
00:12:34
does not change that's not a correct
00:12:36
answer so your answer is changes from
00:12:38
shiny
00:12:39
to that okay
00:12:42
now let's try talking about reaction
00:12:45
with
00:12:46
cold water so here we're talking about
00:12:48
reaction of sodium with cold water
00:12:51
if you put a piece of sodium it has to
00:12:54
be actually a very small piece of sodium
00:12:56
into a beaker containing water what
00:12:59
happens
00:13:00
first of all if i look at the reaction
00:13:02
i'm going to say that sodium is a
00:13:03
reactive metal so it reacts with cold
00:13:06
water and i'm going to tell you that
00:13:09
any metal that reacts with cold water
00:13:12
gives
00:13:13
the hydroxide plus hydrogen gas so
00:13:16
sodium in water will give sodium
00:13:18
hydroxide plus hydrogen
00:13:21
gas now what do we see when we put this
00:13:23
piece of sodium
00:13:25
in the water first of all sodium is in
00:13:27
group one
00:13:28
it it has low density so it floats
00:13:32
on the surface of the water now when it
00:13:35
floats it is
00:13:36
reacting with the water and giving out
00:13:38
bubbles of hydrogen gas
00:13:40
so these bubbles of hydrogen gas will
00:13:42
keep pushing the sodium around on the
00:13:44
surface of the water so we say that the
00:13:46
sodium floats
00:13:48
darts darts means moves around on the
00:13:50
surface of the water
00:13:52
and then it melts or disappears because
00:13:54
it is going to react and it will become
00:13:57
smaller until it disappears
00:13:59
also the bubbles of gas that i'm giving
00:14:01
out are
00:14:02
hydrogen gas so you you will see
00:14:05
vigorous
00:14:06
fizzing or bubbles of gases are coming
00:14:09
out very
00:14:10
quickly now the gases is coming out is
00:14:13
hydrogen gas and hydrogen gas
00:14:15
is flammable so the bubbles of hydrogen
00:14:17
gas
00:14:18
may catch fire if we want a
00:14:21
fourth observation remember that these
00:14:23
are the three most important
00:14:24
observations and he will ask you
00:14:27
what are the observations when sodium
00:14:29
react with cold water
00:14:31
a fourth observation would be the fact
00:14:33
that one because it gives sodium
00:14:35
hydroxide
00:14:36
as a product then the solution is
00:14:39
alkaline and that means if i put litmus
00:14:42
paper what happens
00:14:44
the solution turns litmus paper
00:14:47
to blue because the solution is alkaline
00:14:52
okay you have to know the observations
00:14:55
when we put sodium in cold water
00:14:57
so this is a typical question an example
00:15:00
of a question would be
00:15:01
a teacher investigates the reaction
00:15:03
between sodium and water the teacher
00:15:05
fills a trough of water
00:15:07
she adds a few drops of litmus solution
00:15:09
to the water and then adds
00:15:10
a piece of sodium so she's doing the
00:15:13
experiment that we just talked about
00:15:14
the sodium floats on the water yes we
00:15:17
said that
00:15:18
it reacts with the water and produces
00:15:20
bubbles of hydrogen gas
00:15:21
yes that's correct now he's asking you
00:15:23
to state two
00:15:25
other observations that are made so what
00:15:27
were the
00:15:28
other two observations he has already
00:15:30
said floats
00:15:32
he has already said bubbles or fizzing
00:15:35
so you can't say
00:15:36
fizzing so you can say the sodium darts
00:15:39
and
00:15:40
melts and the litmus solution because he
00:15:43
says that he has
00:15:44
litmus solution in the water the litmus
00:15:46
solution turns
00:15:48
blue okay this is another typical
00:15:51
question that you may be asked to
00:15:52
balance the equation for the reaction
00:15:54
between sodium and water
00:15:56
include state symbols what is the state
00:15:59
symbol for sodium
00:16:01
sodium is a metal so it's solid what was
00:16:03
the state symbol for water
00:16:05
we said water is always a liquid sodium
00:16:08
hydroxide is something that dissolves in
00:16:10
the water so that is
00:16:12
aqueous and hydrogen is a gas and then
00:16:16
you need to balance
00:16:17
can you understand how to balance you
00:16:19
should know how to balance so one sodium
00:16:21
before the arrow one sodium after the
00:16:23
other two hydrogens before the arrow
00:16:25
three hydrogens after the other so that
00:16:28
means that i need to put
00:16:29
a two in front of the water and the two
00:16:32
in front of the
00:16:33
sodium hydroxide that's i that makes it
00:16:36
four hydrogens
00:16:38
but that has ruined the sodium so the
00:16:40
sodium
00:16:41
needs a two in front of it now
00:16:43
everything is balanced
00:16:46
remember do not leave an equation
00:16:48
without balancing even if he doesn't
00:16:50
tell you to balance
00:16:51
lithium and potassium react in a similar
00:16:53
way to sodium when added to water
00:16:56
state why they have a similar reaction
00:16:58
in terms of electronic configurations of
00:17:01
their atoms
00:17:02
so what is common between lithium
00:17:04
potassium and sodium that makes them
00:17:06
react in a similar way
00:17:08
in terms of electronic configuration
00:17:10
electronic configuration means
00:17:12
in terms of the arrangement of the
00:17:13
electrons so the fact that they have
00:17:16
all of them have one electron and outer
00:17:18
shell because they are all in group one
00:17:21
so they all react in the same way now
00:17:24
place the elements lithium potassium and
00:17:26
sodium in order of
00:17:28
reactivity do you remember the activity
00:17:31
if you don't remember the reactivity
00:17:33
series you can just check the periodic
00:17:35
table
00:17:35
you will find that potassium is in the
00:17:38
is at the bottom
00:17:39
sodium lithium and we said the one at
00:17:41
the bottom
00:17:42
is the most reactive so potassium sodium
00:17:45
lithium that is the arrangement of the
00:17:47
reactant
00:17:50
okay another possible question the table
00:17:53
below lists some statements about the
00:17:55
reaction of caesium with cold water
00:17:57
compared to the reaction of lithium with
00:17:59
cold water
00:18:01
so he's comparing lithium to cesium
00:18:03
remember we said where is caesium
00:18:05
caesium is at the bottom of the of the
00:18:08
group one
00:18:08
in the periodic table so which one would
00:18:11
be more reactive the lithium or the
00:18:13
season
00:18:14
of course cesium is at the bottom of the
00:18:16
periodic of the
00:18:17
uh group one in the periodic table so
00:18:20
cesium should be more reactive than
00:18:23
lithium so he's saying i'm comparing
00:18:26
caesium to the reaction of lithium
00:18:30
the first choice is the reaction with
00:18:32
caesium is more
00:18:33
vigorous is that correct yes of course
00:18:36
it is correct
00:18:37
because caesium is more reactive since
00:18:39
it is at the bottom of the
00:18:41
table one the first
00:18:45
group the reaction with cesium produces
00:18:47
a different
00:18:48
gas is that correct no all of them all
00:18:51
the metals will react with cold water to
00:18:54
form
00:18:55
hydrogen gas the reaction with
00:18:59
so uh cesium produces an acidic solution
00:19:01
no
00:19:02
we said what is formed when you act with
00:19:04
cold water is caesium hydroxide
00:19:07
and that's alkali not acidity the
00:19:09
reaction with sediment produces a
00:19:10
different compound
00:19:13
yes of course because cesium will give
00:19:15
you caesium hydroxide why lithium will
00:19:18
give lithium hydroxyl
00:19:20
the reaction of caesium is endothermic
00:19:22
do you remember what we mean by
00:19:23
endothermic
00:19:25
endothermic means you need to heat it in
00:19:27
order to react it takes in heat
00:19:30
or is it exothermic it gives out heat no
00:19:33
reaction of season with water is not
00:19:35
endothermic it is
00:19:36
exothermic now the next question says
00:19:39
write a chemical equation for the
00:19:40
reaction of season with
00:19:42
water again we said season with water
00:19:45
because this is
00:19:46
cold water it will form caesium
00:19:48
hydroxide plus
00:19:50
hydrogen and then you balance in this
00:19:53
way
00:19:54
okay reaction of calcium with
00:19:57
cold water so calcium if it reacts with
00:20:00
cold water it will give exactly the same
00:20:02
it will give calcium hydroxide
00:20:05
plus hydrogen so what am i going to see
00:20:08
now in this case
00:20:10
calcium is in group 2 so it is heavier
00:20:13
than water it is denser than water so it
00:20:15
will sink
00:20:16
so my first observation is that calcium
00:20:19
will sink not float like sodium
00:20:22
but it will still give hydrogen gas so i
00:20:24
will still have strong
00:20:26
fizzing and the solution becomes milky
00:20:29
because the calcium hydroxide that is
00:20:31
formed is not very soluble in water
00:20:34
so slowly and forming some sort of white
00:20:37
precipitate so that makes the solution
00:20:40
milky or cloudy
00:20:43
now when we go to the less reactive
00:20:45
metals because magnesium is less
00:20:47
reactive than the
00:20:48
calcium it will not react with cold
00:20:51
water easily
00:20:53
if i put it in cold water the reaction
00:20:55
is too slow
00:20:57
it will still give magnesium hydroxide
00:20:59
if it's reacting with cold water but it
00:21:00
is very
00:21:01
slow now if i want the reaction to be
00:21:04
quick i have to heat it that means the
00:21:06
water
00:21:07
has to be in the form of steam so i heat
00:21:10
the water soaked cotton wall the
00:21:12
water vapor or the steam passes
00:21:15
over the magnesium ribbon that has been
00:21:19
heated
00:21:20
again remember that the magnesium when
00:21:22
it is heated it burns with a bright
00:21:24
flame and then what is formed magnesium
00:21:28
oxide not hydroxide
00:21:31
so a metal that reacts with cold water
00:21:34
gives the hydroxide
00:21:36
a metal that reacts with steam will give
00:21:39
the oxide magnesium oxide plus hydrogen
00:21:42
so again my observations would be
00:21:45
that magnesium burns with a bright flame
00:21:47
magnesium oxide is a white solid so a
00:21:50
white solid is formed
00:21:51
and hydrogen gas is formed which burns
00:21:54
or we have bubbles of
00:21:55
hydrogen when zinc reacts with steam
00:21:59
again zinc is less reactive so it does
00:22:02
not react with cold water it reacts with
00:22:05
steam and we said when a metal reacts
00:22:07
with steam it forms
00:22:09
the oxide so this forms zinc oxide
00:22:12
plus hydrogen so any metal that will
00:22:15
react
00:22:15
with cold water forms hydroxide so this
00:22:19
is the ones in group one and the bottom
00:22:21
of group two
00:22:23
react with cold water to give hydroxide
00:22:27
the less reactive metals like group 3
00:22:31
and the transition metals they react
00:22:34
with steam
00:22:36
but when they react with steam they form
00:22:39
the oxide
00:22:40
not the hydroxide okay
00:22:44
remember that metals below
00:22:47
hydrogen in the peri in the
00:22:49
electrochemical series
00:22:50
metals that are less reactive than
00:22:52
hydrogen will not react with water at
00:22:55
all
00:22:55
so if i put copper in water it does not
00:22:58
react
00:22:58
at all okay metals with acid
00:23:03
so metal with acid gives
00:23:06
hydrogen gas plus a salt depending on
00:23:09
which metal
00:23:10
so something like magnesium plus hcl
00:23:12
will give hydrogen gas and anything that
00:23:14
gives a gas
00:23:15
gives bubbles of gas now the more
00:23:17
reactive the metal the more the bubbles
00:23:20
so for example magnesium is more
00:23:22
reactive than zinc so the bubbles that i
00:23:24
see
00:23:24
when i react the acid with magnesium is
00:23:27
much more than the ones
00:23:29
formed um when we react it with
00:23:32
zinc now if i put copper in acid
00:23:36
no reaction no bubbles at all again
00:23:39
remember copper is below hydrogen in the
00:23:42
reactivity series so it does not react
00:23:45
with water
00:23:46
it does not react with acids you can't
00:23:49
say copper plus an acid
00:23:52
so a typical question give two
00:23:54
observations that are made when a piece
00:23:56
of magnesium ribbon is added to
00:23:58
acidic solution so you put magnesium in
00:24:00
acid
00:24:01
what two observations would you see
00:24:04
again
00:24:04
we said if i put magnesium in acid like
00:24:07
hcl for example it gives
00:24:09
a hydrogen gas right so what i see would
00:24:12
be bubbles of glass now what's the other
00:24:14
observation
00:24:15
the other observation is that the
00:24:17
magnesium as a solid that i put into the
00:24:19
acid eventually it will start to
00:24:21
dissolve or it will
00:24:23
disappear or it will become smaller
00:24:26
okay so we say the magnesium solid
00:24:28
dissolves or
00:24:31
disappears or becomes
00:24:36
another possible question that you could
00:24:38
see would say something like this
00:24:40
magnesium is a reactive metal
00:24:42
its reactivity can be seen in its
00:24:44
reactions with oxygen dilute sulfuric
00:24:46
acid
00:24:47
and he gives you two reactions one with
00:24:50
oxygen to give magnesium oxide
00:24:52
and one with sulfuric acid to give
00:24:54
magnesium sulfate plus
00:24:56
hydrogen so the first question says in
00:24:59
reaction one some magnesium is ignited
00:25:01
and then placed in a jar of oxygen gas
00:25:04
state two observations that will be made
00:25:06
we said what are the observations that
00:25:09
we see
00:25:10
when we burn magnesium in oxygen
00:25:13
again we said the magnesium burns with a
00:25:16
bright flame
00:25:17
and a white solid is formed because
00:25:20
magnesium oxide is a white solid
00:25:24
the other question is a possible
00:25:27
question that you could have
00:25:29
in an experiment a student adds a piece
00:25:31
of zinc to some dilute hydrochloric acid
00:25:33
in a test tube so it has a piece of zinc
00:25:36
in diabetes
00:25:38
the student measures the temperature
00:25:39
before adding the zinc
00:25:41
after adding the zinc he stairs the
00:25:43
mixture measures the highest temperature
00:25:45
and then he wants to find out if there
00:25:47
is a relationship between the activity
00:25:49
of a metal and the temperature rise
00:25:51
so he repeats the experiment four times
00:25:53
using a different metal each time so
00:25:55
basically
00:25:56
he's putting different methods into the
00:25:59
acid
00:25:59
measuring the initial temperature and
00:26:01
the final temperature so he can
00:26:03
determine how much rise
00:26:05
in temperature there was okay
00:26:08
so state three factors that the student
00:26:11
should keep constants in each
00:26:12
experiment so what the what should he he
00:26:15
should be changing
00:26:16
only the type of metal
00:26:20
but he shouldn't be changing what he
00:26:22
shouldn't be changing the surface area
00:26:23
of the metal
00:26:24
the concentration of the acid the volume
00:26:27
of the acid remember the surface area of
00:26:29
the metal means i shouldn't use
00:26:31
uh one metal in the form of big pieces
00:26:33
and the other matter in the form of
00:26:34
powder for example they should be the
00:26:36
same
00:26:37
surface area and they should be the same
00:26:39
mass of the metal
00:26:41
so you can either say same surface area
00:26:43
of metal
00:26:44
say mass of metal and then the acid
00:26:46
should have the same volume the same
00:26:48
concentration
00:26:50
using information from the table state
00:26:52
the relationship between reactivity of a
00:26:54
metal and
00:26:55
temperature rise so what was the table
00:26:57
this was the table
00:26:59
so magnesium gold iron calcium
00:27:03
what type of reactivity or what is the
00:27:06
arrangement of reactivity of these
00:27:08
muscles you should realize that we said
00:27:10
calcium is more reactive than magnesium
00:27:13
and then this these are more reactive
00:27:15
than iron
00:27:16
and then gold was at the bottom of the
00:27:18
reactivity series and we said it's
00:27:21
not very reactive so when they put it in
00:27:24
acids they found that the more reactive
00:27:27
metal is the one that gives
00:27:28
higher temperature so remember that more
00:27:32
reactivity
00:27:33
is indicated by what is indicated by
00:27:36
more bubbles of gas or by more
00:27:39
rise in temperature so the more reactive
00:27:42
the metal the greater the temperature
00:27:44
rise
00:27:45
states why there is no temperature rise
00:27:47
when gold is added
00:27:48
since there is no temperature rise this
00:27:50
means that gold does not react with
00:27:53
the acid another typical question that
00:27:56
you could see would say the diagram
00:27:58
shows how a student attempts to prepare
00:28:00
some hydrogen gas
00:28:02
state why no hydrogen is produced look
00:28:04
at the
00:28:05
diagram and tell me why do you think he
00:28:06
didn't get any gas
00:28:09
if he didn't get any gas that is just
00:28:11
because
00:28:12
the silver did not react and why doesn't
00:28:15
it react
00:28:16
because it is below hydrogen in the
00:28:18
reactivity
00:28:19
series so he's reacting it with silver
00:28:22
remember that we said
00:28:23
anything below hydrogen in the
00:28:25
reactivity series
00:28:26
will not react with water
00:28:30
or acid so the what which metals do we
00:28:33
have below the reactivity series we have
00:28:36
copper silver gold and we also have
00:28:39
mercury at some
00:28:40
point so silver does not react with
00:28:43
acids because
00:28:44
it is below hydrogen or it is less
00:28:46
reactive than
00:28:47
hydrogen which of these pairs of
00:28:49
chemicals could be used to
00:28:50
safely prepare hydrogen
00:28:54
to prepare hydrogen that means they have
00:28:56
to react with the acid to form
00:28:58
hydrogen and i don't want it to be too
00:29:00
vigorous because he wants it safe
00:29:03
so the first option here a
00:29:06
says copper and acid remember that we
00:29:08
said both copper and gold
00:29:11
and silver are below hydrogen in the
00:29:14
electrochemical series
00:29:16
or the reactivity series so they will
00:29:18
not react with
00:29:20
acids or with water now that means i
00:29:23
have a choice between potassium and
00:29:26
zinc but potassium is in group 1 it is a
00:29:30
very reactive metal if i put it in
00:29:32
acid it will sort of explode or very
00:29:36
violent reaction zinc reacts
00:29:39
but it's not violent so that would be
00:29:42
our
00:29:42
choice okay
00:29:46
the other type of reactions that we have
00:29:48
are displacement reactions a
00:29:50
displacement reaction means
00:29:52
a more reactive metal will push the less
00:29:55
reactive metal out of its salt
00:29:58
so if i have zinc plus copper sulfate
00:30:01
if i have a reaction that means that
00:30:04
zinc is more reactive than coupling
00:30:06
if we do this for two metals
00:30:09
and they don't react that means that
00:30:12
zinc
00:30:12
is not or is less reactive than copper
00:30:15
so when i put zinc in copper sulfate it
00:30:18
will react
00:30:19
because zinc is more reactive than
00:30:21
copper what does it give me it gives me
00:30:23
zinc sulfate plus copper now can you see
00:30:27
the original color of copper sulfate you
00:30:29
should know that
00:30:30
the original color of copper sulfate
00:30:31
solution is blue
00:30:34
but zinc sulfate is colorless so
00:30:38
one observation that you would see is
00:30:40
that the fact that the blue color of
00:30:41
copper sulfate
00:30:43
changes to colorless also i started with
00:30:46
zinc solid and the zinc
00:30:47
reacted in the copper sulfate so at some
00:30:50
point the zinc will dissolve or
00:30:52
start to disappear or become smaller
00:30:55
and then we're forming what we're
00:30:57
forming copper copper metal you should
00:30:59
remember copper metal is
00:31:01
the red or reddish brown metal
00:31:04
so when it forms copper it forms a red
00:31:06
precipitate
00:31:07
in the test tube can you see that so
00:31:10
these are the observations when you put
00:31:12
zinc in copper sulfate now
00:31:15
another example of a displacement
00:31:18
reaction would be magnesium plus copper
00:31:20
carbonate magnesium is more reactive
00:31:22
than copper so it will displace it from
00:31:24
its soles
00:31:25
the copper carbonate is originally a
00:31:28
green color
00:31:30
when it changes into magnesium carbonate
00:31:33
it is now a compound
00:31:34
of group two compounds of group two have
00:31:36
no color
00:31:37
so the solution becomes colorless and i
00:31:40
will start to see a reddish precipitate
00:31:43
of
00:31:43
copper okay a typical question
00:31:47
let's take a look at what type of
00:31:48
question we have
00:31:53
so here he says in an experiment a piece
00:31:55
of zinc metal is placed in a beaker
00:31:57
containing copper sulfate so he was
00:31:59
talking about the ex he
00:32:00
here he's talking about the reaction
00:32:02
between zinc and capacitor fate
00:32:04
the reaction that occurs shows zinc is
00:32:06
more reactive than copper
00:32:08
state to observation so what are two
00:32:10
observations that i will see
00:32:12
when i put zinc in copper sulfate
00:32:15
we said the original color of copper
00:32:17
surface is what
00:32:19
blue so we said the blue solution turns
00:32:22
colorless
00:32:23
and the zinc metal begins to dissolve or
00:32:26
disappear
00:32:27
the diagram shows two ways in which
00:32:29
potassium can be converted into
00:32:31
potassium chloride
00:32:33
give the names of x y and z
00:32:36
so let's take a look at this flow chart
00:32:38
it starts with potassium
00:32:41
he heats it in gas x to form potassium
00:32:45
chloride
00:32:46
so which gas do i react with potassium
00:32:50
to form potassium chloride
00:32:53
i need okay
00:32:56
okay then he says he added water to
00:32:59
potassium
00:33:00
and he got a colorless solution of wine
00:33:03
what happens if i add
00:33:04
water to potassium we said potassium is
00:33:07
a reactive metal it reacts with cold
00:33:09
water
00:33:10
so what i form would be potassium
00:33:12
hydroxide
00:33:15
and then this potassium hydroxide he
00:33:17
wants to react it with an acid
00:33:19
to form potassium chloride which acid
00:33:22
should i
00:33:22
add to potassium hydroxide to form
00:33:25
potassium chloride
00:33:28
hydrochloric acid the acid that has
00:33:31
chlorine in it
00:33:32
and notice that the question said give
00:33:35
the names of these so i have to write
00:33:38
the names of these
00:33:40
you shouldn't write the formulas and if
00:33:42
you do decide to write formula please
00:33:45
write the correct
00:33:46
formula but if he says name give him
00:33:48
name when sodium is burned in iodine gas
00:33:51
sodium iodide is formed
00:33:53
write a chemical equation for the
00:33:54
reaction between sodium and
00:33:56
iodine so i'm going to write a chemical
00:33:59
reaction
00:34:00
sodium plus iv to give what it should
00:34:03
give sodium iodide sodium has a valency
00:34:05
of one and iodine has a valency of one
00:34:07
so i don't write it two
00:34:09
under any of them have i finished
00:34:13
no i have to balance the equation
00:34:16
even if he doesn't say balance a
00:34:18
chemical equation means it has to be
00:34:20
balanced
00:34:20
so you need a two to make the two
00:34:22
iodines
00:34:24
and a two henna to fix the surgery
00:34:27
okay the next thing we're talking about
00:34:31
is rusting of iron
00:34:32
remember that iron when you expose it
00:34:36
iron is originally silver in color so
00:34:38
this
00:34:39
nice clean chain on the right side is
00:34:43
a clean iron that is that hasn't trusted
00:34:46
but when you expose it to the atmosphere
00:34:50
it turns into reddish brown as we can
00:34:54
see
00:34:55
so this is called rust this reddish
00:34:57
brown cover
00:34:58
on the iron is called rust if we're
00:35:01
talking about iron we call it rust if
00:35:03
we're talking about any other metal we
00:35:05
call it
00:35:06
corrosion of eye of of the metal so
00:35:09
all metals corrode corrode means they
00:35:11
react with
00:35:13
water and oxygen in the air
00:35:16
but when we are talking about iron we
00:35:18
can say corrosion of iron or
00:35:20
rusting of iron we don't say rusting of
00:35:22
any other metal
00:35:24
now what do we need for the iron to
00:35:27
rust or for the iron to corrode we can
00:35:30
have an experiment like this in which we
00:35:32
have
00:35:32
males and we have them in different
00:35:34
things so when they put names in
00:35:36
distilled water
00:35:38
and you should remember that distilled
00:35:39
water means water that has
00:35:41
oxygen dissolved in it any normal water
00:35:44
that we have
00:35:45
has a little bit of oxygen dissolved in
00:35:47
it so when we put the nails in distilled
00:35:50
water the nails rust
00:35:53
distilled water contains both water and
00:35:55
oxygen
00:35:56
now if i put the nails in boiled
00:35:59
water now what is boiled water boiled
00:36:01
water is water
00:36:02
that i have boiled so all the oxygen
00:36:05
dissolved in it has escaped
00:36:07
when you boil the water they dissolve
00:36:09
the gases go out
00:36:10
so dissolve the oxygen has gone out it
00:36:12
doesn't have any dissolved oxygen and
00:36:14
i'm covering it with a layer of oil to
00:36:16
make sure that no more oxygen
00:36:18
dissolves in it now when we put the
00:36:20
nails in the boiled water that means i
00:36:22
don't have any oxygen
00:36:24
i find that the nails will not rust now
00:36:27
if i put the nails in another test tube
00:36:29
that contain
00:36:30
anhydrous calcium chloride you should
00:36:32
remember that anhydrous calcium chloride
00:36:35
is
00:36:35
something that absorbs water vapor from
00:36:38
the air
00:36:39
so basically this test tube has no water
00:36:42
and if i leave the nails in this test
00:36:45
tube
00:36:46
the nails will not rust
00:36:49
if we put the nails in sea water now
00:36:52
what is sea water sea water has
00:36:54
water and oxygen and soils so
00:36:57
i will find that in sea water in the
00:36:59
presence of salts or
00:37:01
sometimes in the presence of acid the
00:37:03
nails will
00:37:04
rust very quickly so it's
00:37:08
salt makes the nails rust quickly
00:37:11
so what does the iron basically need in
00:37:14
order to rust
00:37:15
the iron needs both water and oxygen
00:37:18
if you're missing any of them then the
00:37:20
nails do not trust
00:37:22
so the iron requires both water
00:37:25
and oxygen in order to rust now what is
00:37:28
rust
00:37:28
rusting means that the iron changes into
00:37:32
iron iii oxide or actually it is
00:37:35
hydrated
00:37:37
iron iii oxide which is the reddish
00:37:40
brown
00:37:40
flaky uh cover on the
00:37:43
on the iron so what is rust
00:37:47
it is hydrated iron iii oxide that means
00:37:50
the iron is changing to iron oxide and
00:37:53
that means that this
00:37:55
rusting or corrosion is actually an
00:37:58
oxidation process right
00:38:01
and then if we say what is the
00:38:03
appearance of rust rust is reddish brown
00:38:05
and flaky what do you mean by flaky
00:38:08
flaky means it can
00:38:09
peel off it can fall off so this piece
00:38:12
of nail if i leave it
00:38:14
for a long time the rust that forms on
00:38:17
it can
00:38:18
peel off and if the nails are left long
00:38:21
enough they will eventually just change
00:38:23
into
00:38:24
a red brown powder because all of the
00:38:27
rust
00:38:27
peels off okay so
00:38:31
what do we do to prevent trusting i
00:38:33
don't want my
00:38:34
iron objects to rust
00:38:37
so what should i do the first thing that
00:38:40
we normally do or the easiest thing that
00:38:42
we normally do
00:38:43
is painting so if i have railings these
00:38:47
are railings the ones that we
00:38:49
hold on when we go down the stairs or
00:38:52
gates iron gates or windows
00:38:56
the normal thing that we do is paint now
00:38:59
painting
00:39:00
what does painting do painting covers
00:39:03
the iron
00:39:04
so that it prevents it from reacting
00:39:06
with oxygen and water vapor in the air
00:39:09
but the problem with that is if the
00:39:11
layer of paint is peeled off
00:39:13
or scraped off that piece of iron or
00:39:16
that
00:39:17
part of the iron will again start to
00:39:19
rust
00:39:20
so it is something that has to be done a
00:39:23
lot
00:39:23
another method of preventing
00:39:27
rusting would be to coat with oil and
00:39:29
grease when do we use coating of oil and
00:39:31
grease we use it when we're talking
00:39:33
about machines
00:39:34
so if i have a machine in which i don't
00:39:37
want these pieces of iron
00:39:38
to rust or if there's a lot of friction
00:39:41
between them
00:39:42
i coat them with oil or grease
00:39:47
another method would be coating with
00:39:49
plastic now when do we use this
00:39:51
in your dishwasher the racks in the
00:39:53
dishwasher that you put your dishes on
00:39:56
these are pieces of iron that are
00:39:59
coated with plastic again why are we
00:40:02
coating it with plastic to prevent the
00:40:04
iron from
00:40:05
reacting with water and oxygen in the
00:40:09
air
00:40:10
the problem again is if the piece of
00:40:12
plastic
00:40:13
is scraped off or is removed
00:40:17
that exposed surface will again start to
00:40:20
rust
00:40:22
okay a better way of preventing
00:40:25
um rusting would be what we call
00:40:28
galvanizing galvanizing means
00:40:31
covering the iron with a layer of zinc
00:40:34
by dipping or spraying so these are
00:40:37
iron pipes for example or iron tubes of
00:40:40
some sort
00:40:42
i want to prevent it from
00:40:46
rusting so i can dip them into
00:40:49
liquid zinc so that container contains
00:40:53
zinc that is molten molten zinc
00:40:57
and i dip the iron into it or i can
00:41:00
spray it with
00:41:02
zinc the zinc covers the iron
00:41:06
this process is called galvanizing it
00:41:09
prevents rusting because
00:41:11
that outer layer of zinc is a metal that
00:41:15
is more reactive than iron so the zinc
00:41:18
will react and lose electrons and be
00:41:22
oxidized
00:41:23
instead of the iron and the good thing
00:41:26
about it
00:41:27
is even if part of this layer of zinc
00:41:31
is scraped off still the iron will not
00:41:35
rust so long as any part of it is still
00:41:38
touching the zinc
00:41:40
so so long as there is still some zinc
00:41:42
attached to the iron
00:41:44
it is the zinc that will be oxidized not
00:41:47
the iron
00:41:48
do we understand this so covering with a
00:41:50
layer of zinc by dipping your spray that
00:41:52
is called
00:41:53
galvanizing or galvanization
00:41:57
how does it work the zinc is more
00:41:59
reactive than iron
00:42:00
so it loses electrons and becomes
00:42:02
oxidized instead of the iron
00:42:05
and the advantage is even if a piece of
00:42:08
the zinc
00:42:08
is removed still so long as the iron is
00:42:12
touching
00:42:12
something it will not rust or it will
00:42:16
not corrode
00:42:17
okay another method is sacrificial
00:42:19
protection
00:42:20
now sacrificial protection is basically
00:42:22
the same idea but instead of
00:42:25
covering with a layer of zinc i just
00:42:27
attach
00:42:28
a block of a more reactive metal
00:42:31
to the steel or to iron for example
00:42:35
in ships the ship is made of iron i
00:42:38
don't want the ship
00:42:39
to corrode so i just put a zinc
00:42:42
bar attach it to
00:42:45
the side of the ship this presence of
00:42:48
the zinc bar attached to the side of the
00:42:50
ship
00:42:51
prevents the whole ship from rusting
00:42:55
this is because so long as the iron is
00:42:58
touching
00:42:58
some zinc the zinc will react instead of
00:43:02
the ions
00:43:03
since it is more reactive so it will
00:43:05
become oxidized and lose electrons
00:43:07
instead of the eye
00:43:08
so we can use a piece of zinc or we can
00:43:11
use a piece of magnesium for example
00:43:13
bolted to the side of the ship
00:43:16
another method of preventing corrosion
00:43:19
was the electroplating that we talked
00:43:21
about when we were
00:43:23
doing electrons so electroplating
00:43:26
is a reaction with
00:43:30
uh electric current using electric
00:43:33
current
00:43:34
so i attach a piece of i want to cover
00:43:36
my spoon for example
00:43:38
i don't want my spoon to uh corrode so i
00:43:41
cover it i want to cover it with a layer
00:43:43
of silver
00:43:44
so i attach it to the end of the battery
00:43:46
and the other end is attached to a
00:43:48
silver
00:43:50
rod and this reaction is called
00:43:52
electroplating in which the
00:43:54
reaction will occur and cover the zinc
00:43:56
with a layer of
00:43:58
silver of course the let's say when we
00:44:00
cover the spoon with a layer of silver
00:44:02
the silver is something that is less
00:44:04
reactive
00:44:05
than hydrogen so it does not react with
00:44:08
oxygen or water vapor in there
00:44:14
this is a typical question name the
00:44:15
process used to coat iron with zinc
00:44:17
remind me again what was this process
00:44:19
called
00:44:20
when i cover the iron with zinc by
00:44:23
dipping or spraying this is called
00:44:25
galvanizing another question says the
00:44:28
diagram shows three pieces of iron so he
00:44:30
has a piece of iron
00:44:32
not covered with anything a piece of
00:44:34
iron covered with a layer of zinc
00:44:36
and sea has the some of the layer of
00:44:39
zinc
00:44:40
uh peeled off so the three pieces of
00:44:43
iron are left in separate troughs of
00:44:44
water exposed to the atmosphere for
00:44:46
several weeks
00:44:47
the table shows the appearance of the
00:44:49
pieces of iron after several
00:44:51
weeks so after several weeks a was
00:44:54
covered in a brown solid so they did
00:44:55
trust or not
00:44:57
yes we should know that iron as a metal
00:45:00
is shiny when it cover it is covered
00:45:02
with a brown solid that means it has
00:45:04
crusted now b and c remain shiny
00:45:08
so that means that b and c do not rust
00:45:11
the brown solid contains hydrated iron
00:45:14
iii
00:45:15
oxide what is the common name for this
00:45:17
brown solid
00:45:18
so the hydrated iron iii oxide is what
00:45:21
we call
00:45:22
rust identify the two substances that
00:45:25
react with iron to form the brown solid
00:45:27
we said iron needs to react with what in
00:45:29
order to rust
00:45:32
water and oxygen now explain with
00:45:35
reference to the symbol in the box the
00:45:37
symbols in the box
00:45:38
why the brown solid does not form one
00:45:40
see now which one was c
00:45:41
c was the one that was covered with zinc
00:45:44
but a little piece of the zinc is
00:45:46
removed so a little piece of the
00:45:48
iron is exposed but all we still
00:45:52
said that when a little piece of the
00:45:54
iron is exposed
00:45:55
still that will not rust so long as it's
00:46:00
in contact with some zinc so
00:46:03
why is that happening we said this is
00:46:06
because what
00:46:07
zinc is more reactive than i so it loses
00:46:10
electrons instead of iron and becomes
00:46:13
oxidized
00:46:14
so this does not allow the iron to lose
00:46:17
electrons remember that i need to use
00:46:18
the things that are in the box
00:46:20
and no iron ii plus is formed remember
00:46:23
we said
00:46:24
when the ion rusts it changes into ion2
00:46:27
plus
00:46:28
so instead of the iron changing to iron
00:46:30
2 plus it is the zinc that will
00:46:32
react so the zinc reacts loses electrons
00:46:36
becomes
00:46:36
zinc 2 plus instead of the eye
00:46:40
okay so that's the end of this chapter
00:46:44
please study it well and try the
00:46:47
questions that you have in the chapter
00:46:49
asked questions in the pdf that is very
00:46:51
important
00:46:52
it's very important to try the questions
00:46:54
before you go to the next
00:46:56
video that discusses the answers to the
00:46:59
questions
00:47:00
okay thank you