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PROJECT REPORT ON
OPTICAL OPTICA L STUDY OF CO-PRECI CO- PRECIPITA PITATED TED CERIUM MOLYBDO IODATE AND CERIUM MOLYBDO PHOSPHATE NANOPARTICLES
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CHAPTER 1 NANOSTRUCTURED MATERIAL-A BRIEF INTRODUCTION
1.1. Nanotechnology an Nano!ate"#al$ % An #nt"o&ct#on #nt"o&ct#on The roots of Nanotechnology and Nanomaterials can be traced to a lecture deliv deliver ered ed by Richar Richard d Feymann eymann(No (Nobel bel Laure Laureate ate)) in 1959 1959 in a mee meetin ting g of American hysical society! "hen he seculated this future scientists and engineers "ould build structures from atoms and molecules(1)# $e gave a tal%! &There's lenty of Room at the ottom!& at an American hysical *ociety meeting at caltech# Nanotechnology shortened to &nanotech&! is the study of maniulating matter on an atomic atomic an and molecular sca scale# le# +enera +enerally lly!! nanotechnology deals "ith structures si,ed bet"een 1 to 1-- nanometre in at leas leastt one one dime dimens nsio ion! n! and and invo involv lves es deve develo loi ing ng mate materi rial alss or devi device cess osses ossessin sing g at least least one dimens dimension ion "ithin "ithin that si,e# si,e# .uantum mechanical e/ects are very imortant at this scale! "hich is in the 0uantum realm#The realm#The
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+ree% "ord nano2 refers to a dimension !one thousand times smaller than a micron#
R#cha" Fey!ann
Although nanotechnology is a relatively relatively recent develoment in scienti3c research! the develoment of its central concets haened over a longer eriod of time# The emergence of nanotechnology in the 194-s "as caused by the convergence of eerimental advances such as the invention of
the sc scann annin ing g
tunn tu nnel elin ing g
micr mi cros osco coe e in
1941
and
the
discovery
of fullerenes fullerenes in in 1945! "ith the elucidation and oulari,ation of a concetual . fram frame" e"or or% % for for the the goal goalss of nano nanote tech chno nolo logy gy begi beginn nnin ing g "ith "ith the the 1946 1946 ublication of the boo% 7ngines of 8reation#
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The scanning tunneling microscoe! microscoe! an instrument for imaging surfaces at the the atom atomic ic leve level! l! "as "as deve develo loe ed d in 1941 1941 by +er +erd d in innig nig and and $einrich Rohrer at Rohrer at : ;urich Research Laboratory! Laboratory! for "hich they received the Nobel ri ri,e ,e in h hys ysic icss in 1946 1946## Fullerenes "er "ere disc discov over ered ed in 1945 1945 by $arry
of
nanotechnology
and
founded
the
3eld
of molecular
nanotechnology## n 19>9! =reler encountered Richard Fe nanotechnology Feynman ynman's 's 1959 tal% &The &T here re's 's len lenty ty of Roo oom m at the the ott ottom om&# &# The The term term &nano &nanote tech chnol nolog ogy& y&!! originally coined by Norio Taniguchiin Taniguchiin 19>?! "as un%no"ingly aroriated by =reler in his 1946 boo% Engines of Creation: @ne of the roblems facing nanotechnology is the confusion about its de3nition# :ost de3nitions revolve around the study and control of henomena and materials at length scales belo" 1--nm and 0uite often they ma%e a comarison "ith a human hair! "hich is about 4----nm "ide# de# The There has has been been much uch deba debate te on the the fut future ure
imli licati ations ons of
nanote nanotechn chnolo ology gy## Nanote Nanotechn chnolo ology gy has the otent otential ial to creat create e many many ne" mate materi rial alss and and devi device cess "ith "ith a vast vast rang range e of al alic icat atio ions ns!! such such as in medicine!electronics medicine!electronics and energy roduction# sciencebased aroach to Nano!ate"#al$ is a 3eld that ta%es a materials sciencebased nanotechnology## t studie nanotechnology studiess materi materials als "ith "ith morho morholog logica icall featur features es on the nanoscale!! and esecially those that have secial roerties stemming from nanoscale their nanoscale dimensions# Nanoscale is usually de3ned as smaller than a one tenth of a micrometer in at least one dimension! BC D though this term is sometimes also used for materials smaller than one micrometer# micrometer# Nanomateria Nanomaterials ls (nanocryst (nanocrystallin alline e materials materials ) are materials materials ossessing ossessing grain si,es of the order of a billionth of ammeter#A nanocrystalline material
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has grains of the order of 11-- nm#The average si,e of an atom is of the order of 1 to C Angstroms in radius# 1 nanometer comrises 1- AngstromsE hence in one nm there may be to 5 atoms!deending on their radii# Nanocrystalline materials are ecetionally ecetionally strong!hard! and ductile at high tem temer erat atur ures es!" !"ea earr
res esis ista tant nt!c !cor orro rosi sion on
resi resist stan ant! t!
eros erosio ion n
res esis ista tant nt
G
chemically very active#
1.'. Cla$$#(cat#on Cla$$#(cat#o n o) nano!ate"#al$ #
1.'.1. On the *a$#$ o) #!en$#on Nanostructured materials are 8lassi3ed into four di/erent
categories deending on their hysical dimensions#
They are
a. Nano!ate"#al$ #n +e"o #!en$#on,cl&$te"$
This is the recent tye of the nanostructured materials# The ,ero dimensional clusters are being investigated to tailor otical roerties# *olgel rocess has been commonly used to generated clusters#The tyical method of synthesi synthesiss of the the recent recent ,ero ,ero dimensio dimensional nal nanostruc nanostructure tured d materials materials are are the solgel rocess#They are also called 0uantum dots# *. Nano!ate"#al$ #n one #!en$#on%
@ne dimension dimensional al nano structure structure has been called called by a variety variety of name namess incl includ udin ing g "his "his% %ers!3 ers!3br bres es or 3bri 3brids ds!n !nan ano" o"ir ires es or nano nanoro rods# ds#@n @ne e
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dimensional nanostructured materials there "ill be a layered structure or a lamell lamellar ar struct structure ure#H #Haou aourr deosi deositio tion! n! sutte sutterin ring g techni techni0ue 0uess and ele electr ctro o deosition techni0ues have been used to synthesi,e the one dimensional layered nanostructured materials#The magnitude of length G "idth are much greater than the thic%ness of the layered nanocrystals# :onolayerIs(layers that are one atom or molecule) are also routinely mace G used in chemistry# c. Nano!ate"#al$ #n to #!en$#on%
n this nanostructur nanostructured ed materials materials synthesi, synthesi,ed ed are 3lamentary 3lamentary in natu naturre#Th e#The e leng length th subs substa tanc ncia iall lly y lar larger ger than than the the "idt "idth h or dime dimete terr in 3lamentary nanocrystals# T"o dimensional nanomaterials includes tubes G "ires#ecause of 3lamentary nature!this tye of nanostructured materials is refer referre red d to as t"o dimens dimension ional# al#The The tyica tyicall method method of synthe synthesis sis of
t"o
dimensional nanostructured material is chemical vaour deosition#(8H=)
Nano#"e$
Nano"ires are ultra3ne "ires or linear arrays of dots!formed by self assembly#They can be made from a "ide range of materials#*emiconductor Nano Na no"i "irres made made of sili silico con! n!ga gall lliu ium m nitr nitrid ide e G indi indium um hos hosh hid ide e have have demonstrated remar%able otical!electronic G magnetic characteristics#
. Nano!ate"#al$ #n th"ee #!en$#on
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The nanostructured materials are basically in e0uiaed in and are hence called as nanocrystallites or three dimensional nanostructured#The methods commonlyemloyed to synthesis nanocrystalline hase in a variety of mate materi rial alss
are are gas gas
cond co nden ensa sati tion on!m !mec echa hani nica call allo alloyi ying ng G
chem chemic ical al
reciitation and sray conversion rosessing technJ0ues# 1 Nano/a"t#cle$.
Nanoarticles are si,ed bet"een 1G1--nms# Nanorticles may or may not ehibit ehibit si,e related related roerties that di/er di/er signi3cantly from from those observed in 3ne articles or bul% materials# Nanoclusters have atleast one dimension bet"een 1G1-nms and anarro" si,e si,e distribution#Nanoo"ders are agglomerates agglomerates of ultra3ne articles! nanoarticles or nanoclusters#Nanometer si,ed single crystals!or single single domain domain ultra3 ultra3ne ne articl articles es are are often often refer referre red d to as nanocr nanocryst ystals als # Nanoarticles research is currently an area of intense scienti3c interest due to a "ide variety variety of otential alications in biomedical!otical biomedical!otical G electronic 3elds# ' F&lle"ene
A fullerene is any molecule comosed entirely of carbon! in the form of ahollo" shere !ellised!or tube#*herical fullerenes are also called 8arbon 8arbon nanotu nanotubes bes or buc%y buc%ytub tubes# es# Fuller ullerene eness are are simil similar ar in structu structure re to grahite!"hich is comosed of stac%ed grahine sheets of lin%ed heagonal rings #
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F#g.1.1
F&lle"ene
0 Den "#!e"$
=en drimers drimers are sherical olymeric molecules!formed molecules!formed through a nanoscale !hierarchial self assembly rocess#There are many tyes of den drimers E the smallest is several several nanometers in si,e# si,e# =en drimers are used inconventional alications such as coatings G lin%s# 2&ant&! ot$.
Nanoarticles of semiconductors(0uantum dots) "ere theori,ed in the 19>-s and initially created in early 194-s#f semiconductors articles are made small enough! 0uantum e/ects come into lay !"hich limit the energies at "hich electrons G holes can eist in the articles# F#g 1.'
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Fig1#C# reresents the schematic reresentation of the four di/erent tyes of nanostructured materials#
1.'.' Pha$e co!/o$#t#on According to hase comosition nanostructured materials are classi3ed into grous#They are *ingle hase solids
8rystalline !amorhous articles G
:ulti hase solids
Layers etc# :atri comosites!coated articles
:ulti hase systems
etc# 8olloids!aerogels!ferro Kuids etc
Table 1#C#C#8lassi3cation based on hase comosition#
1.'.0 Man&)act&"#ng /"oce$$ +as hase reaction
Flame
Li0uid hase reaction
synthesis!condensation!8H= etc *olgel!reciitation!hydrothermal
:echanical rocedures
rocessing etc# all milling!lasyic deformation etc
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Table 1#C##8lassi3cation based on manufacturing rocess#
1.0. P"o/e"t#e$ o) Nano$t"&ct&"e Mate"#al$ @"ing to the very 3ne grain si,e! nanostructured materials ehibit a variety of roerties that are di/erent and often considerably imroved in com co mari ariso son n "ith "ith thos those e of co conv nven enti tion onal al co coar arse serr grai graine ned d oly olycr crys ysta tall llin ine e materi materials als## f the si,e of the atomi atomicc ensem ensemble ble become becomess comar comarabl able e to or smaller than the tyical length scale of a hysical henomenon! then the satia satiall con3ne con3nemen mentt can a/ect any roerty roerty##
*ome *ome of the roer roertie tiess of
nanostructured materials are given belo"#
,a. Mechan#cal P"o/e"t#e$ 7lasti 7lasticc consta constants nts of nanocry nanocrytst tstall alline ine materi materials als have have been been reduc reduced ed cons co nsid ider erabl ably y co com mar ared ed to thos those e of bul% bul% mater materia ials ls##
This This is due due to the
comara comarativ tivel ely y higher higher inter interat atomi omicc sacin sacing g in the boundar boundary y regio regions# ns# The streng strength th of nanocr nanocryst ystall alline ine materi material al incre increase asess consid considera erably bly than than that that of coarsegrained material# $ardness also increases "ith decreasing grain si,e in conventional conventional coarser grained materials# materials# This relationshi relationshi is called called Hallmaterials hardness decreases "ith Petch "elat#on$h#/3# For nanocrystalline materials decrease in grain si,e# si,e# t is referred referred to as inverse $alle $alletch tch e/ect# n some grains! direct relationshi bet"een oungIs modulus and hardness has been established# Reducing the grain si,e can lo"er lo"er the ductileMbrittle ductileMbrittle transition temeratur temerature# e# The fracture fracture stress of nanocrystal nanocrystalline line material material is lo"er than that of convention conventional al coarsegraine coarsegrained d material# material# +rain si,e si,e and shae! their their
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distribution! ores and their distribution! surface condition! all a/ect the mechanical behaviour of nanocrystalline materials#
,*.The"!al P"o/e"t#e$ The thermal eansion coecient of nanocrystalline material is greatly enhanc enhanced ed due to the rese resence nce of large large amount amount of grain grain boundarie boundaries# s# The sec seci3 i3cc heat heat of a mat materia eriall is clos closel ely y relat elated ed to the the vibr vibrat atio iona nall and and con3gu con3gurat ration ional al entro entroy y of the materi material! al! "hich "hich is direct directly ly relat related ed to the near neares estt neig neighbo hbour ur co con3 n3gur gurat atio ion# n#
The The seci seci3c 3c heat heat in nano nanocr crys ysta tall llin ine e
mate materi rial al is much much high higher er than than that that in the the co coars arser er grai graine ned d mate materi rial al## The The increase in seci3c heat in nanocrystalline material is art attributed to the comli comlicat cated ed struct structur ure e of grain grain and hase hase bounda boundarie ries# s# The enthal enthaly y and entroy of nanocrystalline material is very high#
,c. Elect"#cal P"o/e"t#e$ The electrical resistivity of nanocrystalline na nocrystalline metal is higher than in both coarsegrai coarsegrained ned olycrystall olycrystalline ine metal and alloys# The residual residual resistivi resistivity ty of nanocrystalline metals of --< decreases decreases "ith an increase in in grain si,e# f the crystal si,e is smaller than the electron mean free ath! grain boundary scat sc atte teri ring ng domi domina nate tess and and henc hence e elec electr tric ical al res esis isti tivi vity ty as "ell "ell as the the tem temer erat atur ure e co coe eci cien entt is increa increase sed# d#
t has has been been sho" sho"n n that that the A8
conducting of nanocrystalline Ti@C doed "ith about 1O t is reversible "ith tem temer erat atur ure# e#
The The magn magnit itud ude e of elec electr tric ical al resi resist stiv ivit ity y and and henc hence e the the
condu co nduct ctiv ivit ity y in co com mos osit ites es can be chan change ged d by alte alteri ring ng the the si,e si,e of the the electrically conducting comonent#
,. Magnet#c P"o/e"t#e$. :agnetic roerties of nanocrystalline materials deend on the grain si,e si,e##
t "as "as noted noted that "ith "ith incr increa easi sing ng grai grain n si,e si,e d! the the co coer erci civi vity ty $ c
increases follo"ing d6 o"er la" u to 5-nm! runs through maimum of the
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$c -AMcm and then decreases decreases for grain si,es of about 5-nm decoding to the "ell %no"n %no"n 1Md la" for olycrystall olycrystalline ine magnets# magnets# Nanostructur Nanostructured ed materials materials sho" sho" a reduc reducti tion on in the the sa satu tura rati tion on magn magnet eti, i,ati ation on and ferr ferrom omag agne neti ticc transition temerature! due to the deviations of interatomic sacing in the interfacial region#3 Nano Na noccryst rystal allline ine iron iron base based d allo alloys ys are are used used for for so sofft magne agneti ticc al alic icati ation onss due due to thei theirr sec seci3 i3cc char charac acte ters rs li% li%e lo" lo" co coer erci civi vity ty!! high high ermeability! ,ero magnetostriction! lo" core losses due to high electrical recetiv recetivity ity and good thermal thermal stability stability# :agnetic :agnetic calori3c calori3c e/ect is another another imortant magnetic roerty of nanocomosites5# The magnetic roerty of nanosi,ed article deends on the large surface to volume ratio# Pnli%e bul% mater ateriials als
cons co nsiistin sting g
of
multi ultil le e
magne agneti ticc
dom domains ains!!
sev se veral ral
smal sm alll
ferromagnetic articles can form single magnetic domains! giving rise to sur suram amagn agnet etis ism# m# This This beha behavi viou ourr oen oenss the the ossi ossibl bly y for for al alic icati ation on in information storage#
,e. O/t#cal P"o/e"t#e$ Qhen Qhen the the diam diamet eter er of the the nano nanost stru ruct ctur ured ed mate materi rial al is decr decrea ease sed! d! discrete discrete electroni electronicc energy states states are formed# The eciton eciton ohr radius lay the central role in the otical roerties of semiconductor nanostructures! "hen "hen the si,e si,e of nanost nanostruc ructur ture e comon comonent ent aroac aroache hess the ohr ohr radius radius electronic and otical absortion changes and the integrated absortion can incre increase ase##
f the crystal crystallit lite e si,e si,e of a nanocry nanocrystal stallin line e materi material al becomes becomes
comarable or smaller than deroglie "avelength of the charge carriers generated by the absorbed light! the con3nement increases energy re0uired for absortion# absortion#
This energy energy increase increase shifts shifts the absortionM absortionMlumi luminesce nescence nce
sectra to"ards shorter "avelength "avelength (blue)# The blue shift shift is a 0uantum si,e
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e/ect# e/ect#
7aml 7amle e lue shift shift is observed observed in the lumine luminesce scence nce sectra sectra of
nanocrystalline ;n@ as a function of crystal si,e# 8ontrolling article si,e can change otical roerties of nanostructure samle samles# s#
y controll controlling ing the cluster cluster si,e of 8d*e! 8d*e! *teiger" *teiger"ald ald and urs
(1949) "ere able to synthesi,e clusters of very narro" si,e distributions and sho" sho" that that they they indi indica cate te vary varyin ing g degr degree eess of 0uan 0uantu tum m co con3 n3ne neme ment nt and and di/erent band gas# 8lusters of 1#C1#5nm 1#C1#5nm diameter have a band ga of eH and those having diameter of #5nm have a band ga of C#eH "hile the bul% material have a band ga ga of 1#4eH# 1#4eH# =ue to three dimensional con3nements! con3nements! the me mecha chanis nisms ms for reson resonant ant band band edge edge otic otical al nonli nonlinea nearit ritie iess in nano crystalli crystallites tes are di/erent di/erent from those in bul% materials# materials# @tical @tical and infrared infrared absortion measurements have been erformed for nano crystalline *i 3lm at di/erent di/erent temer temeratu ature res# s# A rono ronounc unced ed red shift of the absort absortion ion "as noticed "ith increasing temeratures u to 5- -8# f deosition temerature "as increased to ?---8 blue shift "as observed "hich sho"s the relation bet"een crystal si,e and deosition temerature
1. Cha"acte"#$t#c )eat&"e$ o) nano$t"&ct&"e nano$t"&ct&"e !ate"#al$ n nano nanost stru ruct ctur ured ed mate materi rial als! s! t"o t"o tye tyess of atom atomss ca can n be distinguished crystal atoms and boundary atoms. *chematic reresentation of hard shere model of an e0uiaed nanocrystalline metal is sho"n in F#g&"e 1.0. and t"o tyes of atoms can be distinguished! of these the 3rst
one
contain ains
crysta stal
atoms
"ith
neare arest
neighbor bor
con3g n3gurati ation
corresonding to the lattice and boundary atoms "ith a variety of inter
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atomic sacing di/ering from boundary to boundary# boundary# A nanocrystaline metal metal contains a large number of interfaces (S61-C5m)"ith random orientation relationshis and conse0uently a substantial fraction of atoms lie in the interfaces interfaces## Assuming Assuming that grains grains have the shae shae of sheres sheres or cubes the volume fraction of the nanocrystaline materials associated "ith the boundary can be calculated as UMd! "here U is the average grain boundary thic%ness and d the average grain diameter diameter## Thus the volume fraction fraction of atoms in the grain boundaries can be as much as 5-O for 5nm grains and decrease to about -O for 1-nm grains and O for 1--nm grains#
Figure 1#
1.3 A//l#cat#on$ o) nanotechnology Qith nanotechnology! a large set of materials and imroved roducts rely on a change in the hysical roerties "hen the feature si,es are shrun%# Nanoarticles! for eamle! ta%e advantage of their dramatically incr increa ease sed d surf surfac ace e area area to volu volume me rati ratio# o# Thei Theirr oti otica call ro roer erti ties es!! e#g# e#g# Kuorescence!! become a function of the article diameter# Qhen brought into Kuorescence a bul% bul% mate materi rial al!! nano nanoart artic icle less ca can n stro strong ngly ly inKu inKuen ence ce the the me mech chani anica call roerties of the material! li%e sti/ness or elasticity# For eamle! traditional olymers can be reinforced by nanoarticles resulting in novel materials olymers "hich can be used as light"eight relacements for metals# Therefore! an incre increasi asing ng soc socie ietal tal bene3t bene3t of such such nanoa nanoarti rticle cless can be eec eected ted## *uch *uch
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nanote nanotechn chnolo ologic gicall ally y enhanc enhanced ed materi materials als "ill "ill enabl enable e a "eigh "eightt reduc reductio tion n accomanied by an increase increase in stability stability and imroved imroved functionality# functionality# There are many alicatons of nanotechnology! fe" of them are sho" here#
a Tissu issue e engi engine neeri ering ng Nanotechnology can hel to reroduce or to reair damaged tissue# Tissue engineering2 ma%es use of arti3cially stimulated cell roliferation by using using suitab suitable le nanoma nanomater terial ialba based sed sca sca/ol /olds ds and gro"t gro"th h factor factors# s# Tissu Tissue e engi engine neer erin ing g migh mightt rel relac ace e today todayIs Is co conv nven enti tion onal al trea treatm tmen ents ts li% li%e orga organ n translants or arti3cial imlants# Advanced forms of tissue engineering may lead to life etension# etension#
b Che!#$t"y an en4#"on!ent 8hem 8hemic ical al ca cata taly lysi siss and and 3ltr 3ltrat atio ion n tech techni ni0u 0ues es are are t"o t"o rom romin inen entt eamles "here nanotechnology already lays a role# The synthesis rovides novel materials "ith tailored features and chemical roerties for eamle! nanoa nanoarti rticle cless "ith "ith a distin distinct ct chemic chemical al surro surroundi unding ng (ligand (ligands)! s)! or seci3 seci3cc otical roerties# n this sense! chemistry is indeed a basic nanoscience# n a shortterm ersective! chemistry "ill rovide novel nanomaterials2 and in the long long run! run! sueri suerior or roce rocesse ssess such such as se self lfass assem embly bly22 "ill "ill enabl enable e energy and time reserving strategies# n a sense! all chemical synthesis can be unde unders rsto tood od in ter terms of nano nanote tech chno nolo logy gy!! beca becaus use e of its its abil abilit ity y to manuf anufac actu turre ce cert rtai ain n molec olecul ule es# Thus Thus!! chem hemistry stry for forms a base base for for nanotechnology roviding tailormade molecules! olymers! etcetera! as "ell as clusters and nanoarticles# nanoarticles#
c 8atalysis 8hemical catalysis ben3ts esecially from nanoarticles! due to the etre treme mely ly larg large e surf surfac ace e to volu volume me rati ratio o#
The The ali alica cati tion on ote otent ntia iall of
nanoarticles in catalysis ranges from fuel cell to catalytic converters and
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hotoc hotocatal atalyti yticc device devices# s#
8ataly 8atalysis sis is als also o imort imortant ant for the roduct roduction ion of
chemicals#
d :edicine The biological and medical research communities have eloited the uni0ue roerties of nanomaterials for various alications# Terms such as biomedical nanotechnology! nanobiotechnology! and nanomedicine are used to describe this hybrid 3eld# Functionalities can be added to nanomaterials by interf interfaci acing ng them them "ith "ith biolog biologica icall molecu molecules les or struct structur ures# es# The si,e si,e of nanomaterials is similar to that of most biological molecules and structuresE ther theref efor ore! e! nano nanoma mate teri rial alss ca can n be usef useful ul for for both both in vivo vivo and and in vitr vitro o biom biome edica dicall rese sear arch ch and and al aliicati ations# ons# Thus Thus far! far! the integ ntegra rati tion on of nanomaterials "ith biology has led to the develoment of diagnostic devices! contrast agents! analytical tools! hysical theray alications! and drug delivery vehicles#
e F#lt" #lt"at at#o #on n A strong strong inKuen inKuence ce of nanoch nanochem emist istry ry on "aste "aste"at "ater er treatm treatment ent!! air uri3cation and energy storage devices is to be eected# :echanical or chemical methods can be used for e/ective 3ltration techni0ues# @ne class of 3ltration techni0ues is based on the use of membranes "ith suitable hole si,es! "hereby the li0uid is ressed through the membrane# Nanoorous membranes are suitable for a mechanical 3ltration "ith etremely small or ores sm smal alle lerr than than 1- nm (na (nano no3l 3ltr trat atio ion n2) and and may be comos comosed ed of nanotubes# nanotubes# Nano3ltration is mainly used for the removal of ions or the searation of di/erent Kuids# @n a larger scale! the membrane 3ltration techni0ue is named ultra3ltration! "hich "or%s do"n to bet"een 1- and 1-nm# @ne imortant 3eld of alication for ultra3ltration is ultra3ltration is medical uroses as can be found in renal dialysis# :agnetic nanoarticles o/er an e/ective and reliable method to remove heavy metal contaminants from "aste "ater by ma%ing use of magnetic searation techni0ues# Psing nanoscale articles
17
increases the eciency to absorb the contaminants and is comaratively ineensive comared comared to traditional reciitation and 3ltration methods5
f In)o"!at#on an co!!&n#cat#on 8urrent hightechnology roduction rocesses are based on traditional to do"n strategies! "here nanotechnology has already been introduced sile silent ntly ly## The The crit critic ical al leng length th sc scal ale e of integrated integrated circuits circuits is already at the nanoscale (5- nm and belo") regarding the gate length of transistors in 8Ps or 8Ps or =RA: devices# =RA: devices#
g Novel Novel semicon semiconduc ductor tor device devicess An eam amle of such novel devices is based on sintronics#The sintronics#The deendence of the resistance of a material (due to the sin of the electrons) on an eternal 3eld is called magnetoresistance# magnetoresistance# This e/ect can be signi3 signi3can cantly tly amli3 amli3ed ed (+:R (+:R +iant +iant :agnet :agnetoR oResi esista stance nce)) for nanosi nanosi,e ,ed d obJects! for eamle "hen t"o ferromagnetic layers are searated by a nonmagnetic layer! "hich is several nanometers thic% (e#g# 8o8u8o)# The +:R e/ect has led to a strong increase in the data storage density of hard dis% dis%ss and made made the the gigab gigabyt yte e rang range e oss ossib ible le## The The so ca call lled ed tunn tunnel elin ing g magnetoresistance (T:R) is very similar to +:R and based on the sin deendent deendent tunneling tunneling of electron electronss through through adJacent adJacent ferromagne ferromagnetic tic layers# layers# oth oth +:R +:R and and T:R T:R e/ e/ec ects ts ca can n be used used to crea create te a non nonvo vola lati tile le main main memo me mory ry for for co com mut uter ers! s! such such as the the so ca call lled ed magn magnet etic ic rando random m ac acce cess ss memory or :RA:# :RA:# n 1999! the ultimate 8:@* transistor develoed at the Laboratory for 7lectronics and nformation Technology in +renoble! France! tested the limits of the the rin rinci cil les es of the the :@*F :@*F7T 7T tran transi sist stor or "ith "ith a diam diamet eter er of 14 nm (aroimately >- atoms laced side by side)# This "as almost one tenth the si,e of the smallest industrial transistor in C-- (1- nm in C--! 9- nm in C--? C--?!! 65 nm in C--5 C--5 and and ?5 nm in C--> C-->)# )# t enab enable led d the the theo theorretic etical al
18
inte integra grati tion on of se seve ven n bill billio ion n Junc Juncti tion onss on a V1 co coin in## $o $o"e "eve ver! r! the the 8:@* 8:@* transistor! "hich "as created in 1999! "as not a simle research eeriment to study ho" 8:@* technology functions! but rather a demonstration of ho" this technology functions no" that "e ourselves are getting ever closer to "or%ing on a molecular scale# Today it "ould be imossible to master the coordinated assembly of a large number of these transistors on a circuit and it "ould also be imossible to create this on an industrial level6#
h Co$!e o$!et# t#c$ c$ @ne 3eld of alication is in sunscreens# The traditional chemical PH rotection aroach su/ers from its oor longterm stability# A sunscreen base based d on mine mineral ral nano nanoa art rtic icle less such such as tita titani nium um dio dioide ide o/er o/er se seve veral ral advantages# Titanium oide nanoarticles have a comarable PH rotection ro roer erty ty as the the bul% bul% mater ateria ial! l! but but lose lose the the co cosm smet etic ical ally ly unde undesi sira rabl ble e "hitening as the article si,e is decreased#
# Ene"gy The most advanced nanotechnology roJects related to energy are storage! conversion! manufacturing imrovements by reducing materials and rocess rates! energy saving and enhanced rene"able energy sources#
J Reduction of energy consumtion A reduction of energy consumtion can be reached by better insulation systems! by the use of more ecient lighting or combustion systems! and by use of lighter and stronger materials in the transortation sector# 8urrently used light bulbs only convert aroimately 5O of the electrical energy into light# light# Nanote Nanotechno chnolog logica icall aroa aroache chess li%e li%e lightemi lightemitting tting diodes diodes (L7= (L7=s) s) or 0uantum caged atoms (.8As) atoms (.8As) could lead to a strong reduction of energy consumtion for illumination#
19
1.5 P"e$ent P"e$ent 7o"8 Nanomaterials have fascinated scienti3c community in recent ast# Nanosi,ed materials are those "hich have articlesorganic! inorganic or combinatio combinations ns that are of nanometer nanometer si,e# si,e# These material materialss ehibit ehibit unusual ro roer erti ties es co com mar ared ed to thei theirr bul% bul% co coun unte ter rar arts ts##
The The synt synthe hesi siss of
nanomaterials "ith uniform article si,e is a subJect of intensive research in recent times because of their fundamental scienti3c interest as "ell as for technological imortance# Acid Acid sa salt ltss of me meta tals ls (T:A (T:A sa salt lts) s) are are obta obtain ined ed in amor amorho hous us and and crys crysta tall llin ine e form# form#
Thes These e co com mou ounds nds have the gene general ral formu formula la :(H :(H))
($W@?)Cn$C@ "here! "here! :(H)X8e!;r!Th!Ti :(H)X8e!;r!Th!Ti etc WX!:o!Q etc# The roerties roerties of the @$ grou of above materials can be echanged for several cations and thus thus these these material materialss are are terme termed d inorg inorgani anicc ion echa echange ngers# rs# A number number of cation can be echanged "ith $Y due to "hich the material ossess cation echange echange roerti roerties es deending deending on the stoitiomet stoitiometry ry of the reagent used! used! temerature at "hich they are mied! rate of addition! mode of miing! $ etc# etc#
The The resu result ltan antt mate materi rial alss vary vary in "ate "aterr co cont nten ent! t! co com mos osti titi tion on and and
crysta crystalli llinit nity y#
Liter Literatur ature e sho"s sho"s that these these materi materials als are "ell "ell studie studied d in
crystalline and amorhous forms# n the the res resen entt "or%! "or%! nano nanoa art rtic icle less of 8e 8eri rium um moly molybdo bdoio ioda date te and and 8eri 8e rium um moly molybdo bdoh hos osha hate te are are synt synthe hesi si,e ,ed d by co cont ntro roll lled ed che!#c che!#cal al coco7=TA as the organic temlating temlating agent# The as /"ec#/#tat#on !etho using 7=TA reared samles are annealed at 5---8 for C hours# hours# The average average crystalline crystalline
20
si,e of both samles are determined from 9-"ay #:"act#on line broadening by using Sche""e" The surf surfac ace e mor morho holo logy gy and and chem chemic ical al Sche""e" e;&at#on e;&at#on# The comosition of both samles are obtained from SEM #th EDA9 techni0ues# The FTR $/ect"&! of both both sa sam mle less are are reco record rded ed for for dete determ rmin inin ing g the the di/er di/erent ent stretc stretchin hing g and bendin bending g fre0u fre0uenc encies ies of molecu molecular lar grou grouss in the samles#
1.6 Re)e"e Re)e"ence nce 1# ($ +leiter!rog#:ater#*ci#(1944)CC#) C#8ristina u,ea! van acheco! and
)# Nanomaterials and Nanoarticles *ources and Toicity2# #N# Taniguchi (19>?)# On the ‘Basic Concept of Nano-Technology’ # roc# ntl# 8onf# rod# rod# London! art ritish *ociety of recision recision 7ngineering# ?#
(1996) 609#
6#*ergey # +ubin (C--9)# Magnetic nanoparticles# QileyH8$# QileyH8$#
21
CHAPTER-'
CHARACTERI
TECHNI2UES
22
'.1. Int"o&ct#on The nanomaterials can be investigated and characteri,ed using di/erent techni0ues li%e Wray di/raction di/ract ion (WR=)! PHHisible PHHisible *ectroscoy(PH *ectroscoy(P H His)!nfrared *ectroscoy(R)! *canning 7lectron :icroscoy(*7:)! Tunneling Tunneling 7lectron :icroscoy(T7:) etc# This chater brieKy describes the theory and instrumentation of Wray di/raction analysis! *7: "ith 7=AW techni0ue and PHvisible PHvisible *ectroscoy *ectros coy##
'.'. 9-Ray D#:"act#on D#:"act# on '.',a.Int"o&ct#on Wray ray =i/r =i/rac acti tion on (WR= (WR=)) is one one of the the most most vers versat atil ile e and and "ide "idely ly emlo em loyed yed eer eerime imenta ntall techni techni0ue 0uess for the struct structural ural charac character teri, i,ati ation on of crystalline materials
# Wray di/raction attern of the samle rimarily give
1-0
information about the di/erent crystalline hases resent=3 # Therefore! the 3rst ste after synthesi,ing the crystalline samle is to record its Wray di/raction attern# Wray di/raction is the most convenient indirect method
23
for the determination of average crystallite si,e of nanocrystalline samles
5-
#
6
'.',*.Theo"y an In$t"&!entat#on Wray o"der di/raction has been used in t"o main areas! for the 3nge nger
rin rint
chara aracteri,ation
of
dete determ rmin inati ation on of thei theirr stru struct ctur ure# e#
crystall alline
materia rials
and
for
the
7ach 7ach crys crysta tall llin ine e so soli lid d has has its its uni0 uni0ue ue
characteri characteristic stic Wray Wray o"der o"der attern! attern! "hich "hich may be used as a
I3nger
rint rintII for for its its iden identi ti3c 3cat atio ion# n# Wray ray crys crysta tall llog ogra rahy hy ca can n also also be used used to dete determ rmin ine e crys crysta tall stru struct ctur ure# e# The The me measu asure reme ment nt of crys crysta tall llin ine e si,e si,e of a olycrystalline secimens by means of Wray is based on the broadening of di/raction lines "hen the crystallite si,e is very 3ne i#e#! less than 1- >m =3 # The broadening of di/raction ea% can be used to determine the si,e of the crystalline samle using the *cherrer e0uation#
*cherr errer e0uation is!
t X -#9 #9λM\h%l8os θh%l
raggIs la" is given by! Cdsin] X n^ ___________## (1) For 3rst order di/raction! Cdsin] X ^_____________ ^_____________ (C) :ultilying both sides by an integer m such that md Xt! thic%ness of the crystal Ctsin] Xm ^________########## () 70n(C 70n(C)! )! can also also be inter interre reted ted as the the mth order reKection from a set of lanes "ith interlanar distanceItI# =ifferentiating both sides of ()! remembering m ^ is a constant# Ctcos] ` ] YCsin ] ` t X-____ (?)
24
` ] can be ositive or negative# 8onsidering magnitude only (?) leads to tX`tsin]M ` ]cos] *ince the smallest increment increment in in tI is d! using using ` tXd! and substituting ^MC for dsin] Bfrom (C)D! "e get tX ^MC`]cos]_________## (5)
A
I
AI 8>
8 =
]Y`]
=I
1 C
:I N
:
L ]
tXmd LI
NI
25
#
F#g&"e %'.1
Let ]1 X ] Y` ]! be the highest ossible angle that can be got before comlete destructive interference and let ] CX] [` ] be lo"est angle that can be got before comlete destructive interference# No" "e can interret C`] as the angular "idth of the Wray di/raction line# n the Wray di/ractome di/ractometer ter "hat is recorde recorded d is the variation variation in intensity of the diffraction lines "ith C]! so in the Wray diffractogram "e can see diffracted Wrays over all scattering angles bet"een C] 1andC]C# f "e assume a triangular shae for the ea%! the full "idth at half maimum (FQ$:) "ill be! \
X
X
]1]C
(C]1 C]C ) MC
X (] Y` ]) [ (] [` ]) \
X
C ` ]____________ (6)
ma
ntensity maMC#
_#\_#
26
C]C
C]
C]1
F#g&"e%'.'
=iffraction from finite thic%ness crystal! substituting \ for C`] on (5)! "e get t
X
^M\ 8os]___________## (>)
This is essentially the *cherrer *cherrer e0uation# A more more rigo rigoro rous us trea treatm tmen entt (usi (using ng a +aus +aussi sian an func functi tion on!! rathe ratherr than than a triangular function) gives! t
X
-#9^ M\ 8os]_______ (4)!
for
sherical
crystal of diameter t# t
X
%^ M\h%l 8os]h%l
$ere!t is the average crystallite si,e normal to the reKecting lanes !% is the shae factor! "hich lies bet"een -#95 and 1#15 deending uon the shae of the grains in the "ave length of Wray used and \ h%l is the Full Qidth at $alf :aimum(FQ$:) of the diffraction in radians and ] h%l is the ragg angle corresonding to the di/raction line arising from the lanes designated by the :iller :iller indices(h%l indices(h%l))6#
27
F#g&"e%'.0.E?/e"#!ental F#g&"e%'.0.E?/e"#!e ntal $et &/ )o" 9RD
9-Ray #:"acto!ete"
28
'.0. Scann#ng Elect"on M#c"o$co/e #th EDA9 '.0.1. Int"o&ct#on *7: *7: stan stand ds for for sc scan anni ning ng elect lectrron mic micros osco coe e##
The The *7: *7: is a
microscoe that uses electrons electrons instead of light to form an image# *ince their deve develo lom men entt in the the ea earl rly y 195195-'s! 's! sc scan anni ning ng elec electr tron on micr micros osco coe ess have have deve develloe oed ne" ne" area areass of stu study in the the medic dical and and hy hysic sical sc sciienc ence communiti communities# es# The *7: has allo"ed allo"ed researchers researchers to eamine eamine a much bigger bigger variety of secimens# The scanning electron microscoe has many advantages over traditional traditional microsc microscoes# oes# The *7: has a large large deth of 3eld! "hich allo"s allo"s more more of a secime secimen n to be in focus at one time# time# The *7: also also has much higher resolution! so closely saced secimens can be magni3ed at much higher levels# ecause the *7: uses electromagnets electromagnets rather than lenses! lenses! the resea researc rcher her has much much more more contr control ol in the degree degree of magni3 magni3cat cation ion## All of these advantages! as "ell as the actual stri%ingly clear images! ma%e the scanning electron microscoe one of the most useful instruments in research today#
29
F#g&"e%'.
:orhological studies of the samles are done using scanning electron microscoy# *7: is a very ecient tool to study the surface tetures of materials# $ere the surface of the samle is irradiated "ith a beam of accelerated electrons# *ince electrons have shorter "avelengths comared to hotons! the resolution obtained in *7: is very high comared to that in conventional otical microscoy# Furthermore! the deth of focus in *7: is much greater than that achieved in otical microscoy# n addition to the above t"o factors! it has the advantage of greater magnifying o"er and henc hence e *7: *7: has has beco become me a very very o"e o"erf rful ul tech techni ni0u 0ue e to elo lore re the the free free surfaces of materials# The energy disersive sectrum of the samle are also sho"n along "ith the *7: image# The *7: is an instrument that roduces a largely magni3ed image by using electr electrons ons instead instead of light to form an image# A beam of electrons electrons is rodu roduced ced at the to of the micros microsco coe e by an electro electron n gun# gun# The electr electron on beam follo"s a vertical ath through the microscoe! "hich is held "ithin a vacuum# The beam travels through electromagnetic electromagnetic 3elds and lenses! lenses! "hich focus the beam do"n do"n to"ard to"ard the samle# @nce the beam beam hits the samle! samle! electrons and Wrays are eJected from the samle#
F#g&"e%'.3
30
=etect =etectors ors collec collectt these these Wrays! rays! bac%sc bac%scatt atter ered ed ele electr ctrons ons!! and sec second ondary ary electrons and convert them into a signal that is sent to a screen similar to a television screen# This roduces the 3nal image# image#
'.0.'.In$t"&!entat#on%
F#g&"e%'.5 SEM o/ene $a!/le cha!*e"
The *7: micrograhs of our samles are obtained "ith a $itachi :odel *---$ electron microscoe# The electron beam is focused on selected area areass of the the sa sam mle less ac acco cord rdin ing g to the the re0ui e0uirrem emen ents ts and and at di/e di/errent ent magni3 magni3cat cation ion## The %ineti %ineticc energ energy y ac0uir ac0uired ed by ele electr ctrons ons in an elect electro ron n column! "hen they are accelerated through an electric 3eld! is transferred to the samle and its dissiation yields a variety of signals available for analysis of elec electr tron on from from the the high highes estt oc occu cui ied ed mole molecu cula larr orbi orbita tall to the the lo"e lo"est st available un3lled molecular orbital# n most of the cases! several transitions occur resulting in the formation of several s everal bands#
31
The most most imor imortan tantt roer roerty ty of a sem semico icondu nducto ctorr nanost nanostruc ructur ture e is its its otical behavior to crystallite si,e# @tical roerties may be absortion! sectral s ectral resonse!
hotoluminescence!
hotoluminescence
ecitation!
electroluminescence and Raman scattering "hose otical roerties resond to crys crysta tall llin ine e si,e si,e## As the the si,e si,e is decr decrea ease sed! d! the the elec electr tron onic ic stat states es are are disc discre reti ti,e ,ed d and and resu result ltss in "ide "ideni ning ng of the the band band ga and and incr increa ease sess the the oscillator strength# The radiative recombination life time of carrier is lo"ered from nanosecond to icoseconds# These features %no"n as 0uantum si,e e/ect (.*7) are observed in semiconductor nanocrystals#
'.. Fo&"#e" T"an$)o"! In)"a"e S/ect"o$co/y '..1. Int"o&ct#on
*ectroscoy is the study of interaction of electromagnetic radiation
"ith matter# nfrared *ectroscoy is one of the most o"erful analytical techni0ues "hich "hich o/er the ossibility of of chemical identi3cation# @ne of the most imortant advantages of R sectroscoy over the other usual methods of structural analysis is that it rovides useful information about the structure of molecul molecule e 0uic%ly 0uic%ly## This This techni techni0ue 0ue is based on the fact that that a chemi chemical cal substance sho"s selective selective absortion in in the infrared region# After After absortion of R radiation! the molecule of a chemical substance vibrate at many rate of vibration giving rise to ac%ed absortion band! called R absortion sectra# Harious bands "ill corresond to the characteristic functional grous and bond resent resent in a chemical chemical substance# substance# Thus an R sectrum sectrum of a chemical chemical substance is 3ngerrint for its identi3cation# A mole molecu cule le abso absorb rbss radi radiati ation on only only "hen "hen the the natu natural ral fre0 fre0ue uenc ncy y of vibration of some art of a molecule is the same as the fre0uency of the radiation# The molecules molecules vibrate at increased increased amlitude# This occurs at the eense of the energy of R radiation "hich "hich has been absorbed# n nfrared sectroscoy! the absorbed energy brings about redominant changes in the vibrational energy "hich deend uon
32
(a) :ass of the atom resent in the molecule (b) *trength of the bond (c) The arrangement of atom "ithin the molecule# t has been found that no t"o comounds ecet the enantiomers can have have similar similar nfrare nfrared d sectr sectra# a#
Qhen Qhen infrar infrared ed light is assed through through
sam sa mle le!! the the vibr vibrat atio iona nall and and rota rotati tion onal al ener energi gies es of the the mole molecu cule le are are increased# T"o tyes of fundamental vibrations vibrations are stretching and bending# bending# n stretching vibrations! the distance bet"een the t"o atoms increases or decre decrease asess but the atom remain remain in the same same bond ais# ais#
ut in bending bending
vibrations the osition of atoms changes "ith resect to the original bond ais# There are t"o tyes tyes of stretching vibrations# Also there there are four tyes of bending vibrations scissoring! roc%ing! "agging and t"isting# Another condition for a molecule to absorb R radiation is its electric diole# A molecule can only absorb R radiation "hen "hen its absortion causes causes a change in its electri electricc diole# diole# A molecule molecule is said to have an electric electric diole! diole! "hen there is a slight ositive charge and a slight negative charge on its comonent atoms#
'..'. In$t"&!entat#on The aaratus for measuring infrared sectra is di/erent from that for visible and ultraviolet regions because the otical materials li%e glass and 0uar 0uart, t, absorb absorb stron strongl gly y in the infr infrar ared ed regio region# n#
The The main main arts arts of an R
sectrometer sectrometer are as follo"s#1a b c d
The The R radi radiat atio ion n sour source ce## The The mon monoc ochr hrom omat ator ors# s# The samle samle cells cells and and sam samlin ling g of subs substan tance ces# s# =etectors#
33
F#g&"e% '.6 ,a The IR "a#at#on $o&"ce
The various oular sources of R radiations are! i
ncandescent la lam n the near infrared instruments an ordinary incandescent lam is
generally used! "hich fails in the far infrared# ii Ne Nerrnst nst glo" glo"er er t consist of a hollo" rod "hich is about Cmm in diameter and -mm in length! "hich is non conducting at room temerature and must be heated by eternal means to bring it to a conducting conducting state# The main disadvantage disadvantage of Nernst glo"er is that it emit R radiation over "ide "avelength range! the intensity of radiation constant over long eriod of time# iii +lo"er +lo"er source source t is a rod of sintered silicon carbide "hich is about 5-mm in length length and ?mm in diameter diameter##
Pnli% Pnli%e e the Nernst Nernst glo"er glo"er it is self
starting starting and more satisfactory satisfactory## The main disadvantage disadvantage is that it is a less intense source than the Nernst glo"er#
34
(iv) :ercury arc t is used in far infrared instrument# ,* Monoch"o!ato"
The radiation source emits radiation of various fre0uencies as the samling electron electronss absorbs at certain certain fre0uency fre0uency## t is necess necessary ary to sel select ect desired desired fre0 fre0ue uenc ncy y from from the the radi radiat atio ion n so sour urce ce##
This This se sele lect ctio ion n is advi advise sed d by
monochromators! "hich are mainly of t"o tyes! rism monochromator and grating monochromator# ,c Sa!/le cell$ cell$ an $a!/l#ng o) $&*$tance$
*amle can be solid! li0uid or gas# ut it should should be contained in a cell transaren transarentt to R radiation# *amle *amle cells are are usually made made of al%ali metal metal halides such as sodium chloride! otassium bromide etc# Sa!/l#ng o) $ol#$
Four techni0ues are generally emloyed for rearing solid samles# These are *olid run in solution f the solution of solid can be reared in a suitable solvent then the solution is run in one of the cells for li0uids# li0uids# ut this method cannot cannot be used for all solids because suitable solvent are limited in number and there is no single solvent "hich is transarent throughout the R region# (ii) *olid 3lms f the solid is amorhous in nature! the samle is deosited on the surface of <r or Na8l cell by evaoration of a solution of the solid# iv :ull techni0ue techni0ue n this techni0ue! the 3nely ground solid samle is mied "ith nuJol (mineral oil) to ma%e a thic% aste "hich is then made to sread bet"een R transmitting "indo"s# Qhen R sectrum of a solid samle samle is ta%en ta%en in nuJol mull! absortion bands of the samle that haen to coincide "ith the absortion band of the nuJol mull "ill be hidden! but others "ill be clearly
35
seen in the R sectrum# This method is good for 0ualitative analysis analysis but not for 0uantitative analysis# v ress ressed ed ell ellet et techni techni0ue 0ue n this techni0ue a small amount of 3nely ground solid samle is intimately mied "ith about 1-- times its "eight of o"dered otassium bromide# The 3nely ground ground miture is is then assed under very high ressure in a ress to form a small ellet (about 1Cmm thic% and 1cm in diameter)# The resulting ellet ellet is transarent to R radiation and is run as such# A4antage$
1 <r ell ellets ets can can be stor stored ed for for long eri eriod od of time# time# C As the conce concent ntrat ratio ion n of the saml samle e can be suit suitabl ably y adJu adJust sted ed in the ellets! it can be used for 0uantitative analysis# The reso resolut lution ion of the sect sectrum rum in the <r <r is suerior suerior to that that obtaine obtained d "ith mulls# D#$a4antage$
1 The The high high res ressu sure re invol involve ved d duri during ng the the form format atio ion n of ell ellet etss may may brin bring g about olymorhi olymorhicc changes changes in crystallin crystallinity ity in the samles! samles! "hich may cause comlication in R sectrum# C This This method method is not succes successfu sfull for some oly olymer merss "hich "hich are dicul dicultt to grind "ith <r# From the above discussion "e %no"s that one may emloy the NuJol method for running crystalline comounds in the solid and may reserve the <r ellet method for remaining solid samles# Detecto"$
T"o T"o main tyes are in common use! one sensing the heating e/ect of radiation! the other deending u on hotoconductivity hotoconductivity## n the near infrared regi region on hot hotoc ocon ondu duct ctiv ivit ity y ce cell ll is gene genera rall lly y used used that that is the the radi radiat atio ion n is allo"ed to fall on hoto conducting material and conductivity of material meas me asur ured ed co cont ntin inuo uous usly ly by a brid bridge ge net" net"or or%# %#
Psual Psual R dete detect ctor orss are are
thermocoule! thermisters! golay cell! hotoconductivity cell! bolo meters etc#
36
'.3. Re)e"ence$ 1# Z * lac%more! in oli! state "hysics! *econd 7dition! 8ambridge Pniversity ress! 8ambridge (1945)# C# Z *rivasthava! in Ele#ents of oli! tate physics rentice$all rentice$all ndia! Ne" =elhi (C--1)# # 8#4)# 6# *uryanarayana 8#! ull#:at#*ci# 1> (199?) (0)# ># A 8ervellnio! 8 +iannini! A +uagliardi and : Ladisa* "hy+,e+B+>C (C--5) 0(./1# (7lectronic version)#
4# R Zamuto"s%i!Z#R#F Zamuto"s%i!Z#R#Ferraro! erraro! and =#8 Lans%i! *ectroscoy!>(199C) *ectroscoy!>(199C) 11E #R! Altemose! Z#8hem#7duc! 6 6 (1946) (1946) 216! AC6C#
9# *%oog! $oller and Nieman! in "rinciples of $nstr%#ental 2nalysis ! Fifth edition#
37
a n! pectroscopy* pectroscopy* II (C-->)194C--# 1-# +#Aruldhas! Molec%lar tr%ct%re an!
#
CHAPTER-0 S@NTHESIS AND CHARACTERI
38
0.1. Int"o&ct#on 8hemistry has layed a maJor role in develoing the materials "ith ne" and technologically imortant roerties# The advantage of chemical synthesis is its versatility in designing and synthesi,ing ne" materials that can be re3ned re3ned into 3nal roducts# roducts# The rimary rimary advantage advantage is that chemical chemical methods o/ers miing at molecular level# $o"ever the bene3ts of emloying sim simle le and and co cost st e/ e/ec ecti tive ve chem chemic ical al roc roces essi sing ng me meth thod odss are are "ide "idely ly recogni,ed and a areciated
1-3
#The #The ro roe erti rties and and al alic icat atio ion n of
nanoa nanoarti rticle cless are largel largely y deend deendent ent on their their si,e! si,e! shae shae and tet teture uress5# 8ons 8o nsid ider erab able le atte attent ntio ion n has has been been dra" dra"n n to"a to"arrds the the si,e si,e and and sha shae e contr controll olled ed synthe synthesis sis of nanost nanostruc ructur tured ed materi materials als
# =eending uon the
1-0
seci3c re0uirements such as material to be synthesi,ed! the grain si,e and maimum ermissible si,e distribution! urity of samle re0uired! 0uality of samle samle gener generate ated d etc#! etc#! di/er di/erent ent me metho thods ds are em emlo loye yed d for synthe synthesi, si,ing ing nanohase materials# n the resent study! nanocrystalline cerium molybdate and cerium cerium molybdoiod molybdoiodate ate "ere "ere synthesi,e synthesi,ed d through through controlle controlled d chemical chemical reciitation method#
0.'. 0.'. Sa!/ Sa!/le le /"e/ /"e/a" a"at at#o #on n an an E?/e E?/e"# "#!e !ent ntal al P"oce&"e Nanoart Nanoarticl icles es of 8erium 8erium :olybd :olybdoio oiodate date "ere "ere rea reare red d by contr controll olled ed co reciitation method using analytical grade chemicals# *odium :olybdate! ottasi o ttasium um odate odate and Ammonium Ammonium ceric sulhate sulhate "ere "ere used as the starting materials# 7=TA "as used as the stabili,er# A0ueous solutions of *odium
39
:olybdate (-#1:! 5- ml) Ammonium ceric sulhate (-#1:! 5-ml) ottasium iodate (-#1:! 5-ml) 5-ml) and 7=TA(-#-1C5:! 7=TA(-#-1C5:! 55- ml) "ere slo"ly mied mied dro "ise "ise into into a conical conical Kas% Kas% and it it is stirr stirred ed "ell "ell using using a magne magnetic tic stir stirre rerr # This rocess is to be done in one hour# The stabili,er 7=TA "as used to revent gro"th and agglomeration of the articles# n this rocess the article si,e is is gove goverrned ned by the the eer erim imen enta tall ara arame mete ters rs li% li%e co conc ncen entr trat atio ion n of the the reactants! rate of miing! $! Hiscosity of the solutions etc6# t is imortant to note that the stabili,ers used for controlling the reciitation reaction should be easily and comletely removable from the samle so as to avoid any ossible contamination of the samles#The metal molybdoiodate reciitate formed "as "ashed several times in distilled "ater to free it from ions and othe otherr imu imuri riti tie es# The "et re recii ciita tate te obta obtaiined ned "as dri dried at roo oom m temerature and thoroughly ground using an agate motor to obtain the 8erium 8erium :olybdoiodate :olybdoiodate recursor recursor in the form of a 3ne o"der# o"der# The 8erium :olybdoiod :olybdoiodte te recursor recursor material material "as treated treated "ith 1N $8l#The $8l#The acid treated treated 8erium 8erium :olybd :olybdoio oiodat date e recur recursor sor "as anneal annealed ed at 5-5--o8
for for C hour hourss to to
reare nanoarticles of 8erium :olybdoiodate# Nanoarticles of 8erium :olybdohoshate "ere reared by controlled co reciitation method using analytical grade chemicals# *odium :olybdate! =isodium hydrogen otho hoshate and Ammonium ceric sulhate "ere used as the starting materials# 7=TA "as used as the stabili,er# A0ueous soluti sol utions ons of *odium *odium :olybd :olybdate ate (-#1: (-#1:!! 5- ml) ml) Ammon Ammonium ium ceric ceric sulhat sulhate e (-#1 (-#1:! :! 5-ml 5-ml)) ! =iso =isodi dium um hydr hydrog ogen en otho othoh hos osh hat ate e (-#1 (-#1:! :! 5-ml 5-ml)) and and 7=TA(-#-1C5: 7=TA(-#-1C5:!! 5- ml) "ere slo"ly mied mied dro dro "ise "ise into a conical conical Kas% and it is stirred "ell using a magnetic stirrer # This rocess is to be done in one hour#The hour#The 8erium :olybdohoshate recursor recursor material "as treated treated "ith 1N $8l#The $8l#The acid acid treat treated ed 8erium 8erium :olybd :olybdoh ohos oshate hate recu recurso rsorr "as anneal annealed ed 5--o8 for C hours to reare reare nanoarticles of 8erium :olybdohoshate# :olybdohoshate# The samle code "as assigned to the four samles along "ith annealing temerature and duration of annealing is sho"n in Ta*le.0.1 #
40
Ta*le.0.1
0.0.
*amle
Annealing
=uration of
code
Temerature Temerature
annealing
CMI
-
-
CMI 3
3oC
'h"$
CMP
-
-
CMP 3
3oC
'h"$
Reco"#ng o) 9-"ay D#:"act#on /atte"n The Wray Wray di/raction attern of the samles CMI=CMI 3=CMP and CMP 3
"ere recorded using 9PERT-PRO o"d o"der er di/r di/rac acto tome mete terr (PAN
analytical! Netherlands) emloying C&- radiation # Fitted curve
CMI
200
) s t i 150 n U . b r A ( y t 100 i s n e t n I
50
0
0
10
20
30
40
50
60
70
80
90
2
F#g&"e.0. 1 9RD /atte"n o) CMI
:easurement 8onditions
=ataset Name
8: 5--
41
File name 8W'ert =atageneral* N 8ollege8: 5--#rdml 8omment 8on3gurationXFlat *amle *tage! @"nerXPser1! 8reation dateX1-M9MC--4 C19 : +oniometerXQ-5-M6+oniometerXQ-5-M6- (ThetaMTheta)E :inimum ste si,e CTheta-#--1E :inimum ste si,e @mega-#--1 *amle stageXQ->1M stageXQ->1M rac%et =i/ractometer =i/ra ctometer systemXW7RT systemXW 7RTR@ R@ :easurement rogramX+eneral 1-9-! @"nerXPser1! 8reation dateX?MCMC--9 1C-19 : :eas :easur urem emen entt =at =ate e M Tim Time e 4M1> 4M1>MC MC-1 -11 1 1 11 111 11 : @erator N*T Ra" =ata @rigin WR= measurement (#WR=:L) *can Ais +onio *tart o osition B BCTh#D 1-#-19? 7nd osition BCTh#D 49#94>? *te *i,e BCTh#D -#-1>*can *te Time BsD 1-#>1 *can Tye 8ontinuous *= :ode *canning *= Length BCTh#D C#1C @/set BCTh#D -#---=ivergence *lit Tye Fied =ive =iverg rgen ence ce *li *litt *i,e *i,e BD BD -#? -#?5? 5? *ec *ecim imen en Len Lengt gth h BmmD BmmD 1-#1-#-:eas asu urement Te Temerature B B8D C5#-Anode :aterial 8u <Alha1 BD 1#5?-6+enerator *ettings - mA! ?- %H =i/ractometer Tye --------11-?551 =i/r =i/rac acto tome mete terr Numb Number er +oniometer Radius BmmD C?-#-=ist# Focus=i Focus=iver verg# g# *lit *lit BmmD 1--#-1--#-ncident eam :onochromator No *inning No
42
ounts #$ 500
80
60
40
20
0 20
30
40
50
60
70
80
Position [°2Theta] (o!!er (u""
F#g&"e.0. '.9RD /atte"n o) CMI 3
ea% List os# BCTh#D C4#C>C 56#?5 >?#>>4-
$eight BctsD ?>#64 6#66 >#46
FQ$: BCTh#D -#?-4-#9>9C -#C-?-
dsacing BD #15>4> 1#6159 1#C6456
Rel# nt# BOD 1--#-1#9> 16#?4
43
%&!eri'enta data
#P
14
12 ) s t i n 10 U . b r A ( 8 y t i s n e t n 6 I
4
2
0 0
20
40
60
80
100
2
F#g&"e.0. 0.9RD /atte"n o) CMP
:easurement 8onditions =ataset Name 8: 5-File name 8W'ert =atageneral* N 8ollege8: 5--#rdml 8omment 8on3gurationXFlat *amle *tage! @"nerXPser1! 8reation dateX1-M9MC--4 C19 : +oniometerXQ-5-M6+oniometerXQ-5-M6- (ThetaMTheta)E :inimum ste si,e CTheta-#--1E :inimum ste si,e @mega-#--1 *amle stageXQ->1M stageXQ->1M rac%et =i/ractometer =i/ra ctometer systemXW7RT systemXW 7RTR@ R@ :easurement rogramX+eneral 1-9-! @"nerXPser1! 8reation dateX?MCMC--9 1C-19 : :eas :easur urem emen entt =at =ate e M Tim Time e 4M1> 4M1>MC MC-1 -11 1 C C6 6?6 ?6 : @erator N*T Ra" =ata @rigin WR= measurement (#WR=:L) *can Ais +onio *tart o osition B BCTh#D 1-#-19? 7nd osition BCTh#D 49#94>? *te *i,e BCTh#D -#-1>*can *te Time BsD 1-#>1 *can Tye 8ontinuous *= :ode *canning
44
*= Length BCTh#D C#1C @/set BCTh#D -#---=ivergence *lit Tye Fied =ive =iverg rgen ence ce *li *litt *i,e *i,e BD BD -#? -#?5? 5? *ec *ecim imen en Len Lengt gth h BmmD BmmD 1-#1-#-:eas asu urement Te Temerature B B8D C5#-Anode :aterial 8u <Alha1 BD 1#5?-6+enerator *ettings - mA! ?- %H =i/ractometer Tye --------11-?551 =i/r =i/rac acto tome mete terr Numb Number er +oniometer Radius BmmD C?-#-=ist# Focus=i Focus=iver verg# g# *lit *lit BmmD 1--#-1--#-ncident eam :onochromator No *inning No
ounts #P 500
60
40
20
0
20
30
40
50
60
70
80
Position [°2Theta] (o!!er (u""
F#g&"e.0. .9RD /atte"n o) CMP 3
ea% List os# BCTh#D C5#1>C9 C4#495C 1#-1? ?1#9?56 ?4#146-
$eight BctsD 9#1C #?9 >#4? 1>#4? 1>#--
FQ$: BCTh#D -#9>9C 1#1?C? -#?496 -#65C4 -#65C4
dsacing BD #5?9#-4>?? C#455> C#15C1 1#4469>
Rel# nt# BOD C?#144#51 1--#-?>#1? ??#9
45
0.. DETERMINA DETER MINATION TION OF AERAE CR@ST CR@STALLITE ALLITE SI
Wray Wray di/raction line broadening! "ithout
ta%ing ta%ing instrumental instrumental correcti correction on to line broadenin broadening# g# *cherrer *cherrer e0uation e0uation is the simlest method of determining the average si,e of nanocrystalline samles from Wray di/raction line broadening# *cherrer e0uation4 is! t 8G ,h8l !ea$&"eco$ Jh8l
$ere! t is the average crystallite si,e normal to the reKecting lanes! % is the shae factor "hich lies bet"een -#95 and 1#15 deending on the shae of the grains (%X1 for sherical crystallites)! ^is the "avelength of Wray used and (\h%l) measured is the measured FQ$: of the di/raction line in radians and h%l is the ragg angle corresonding to the di/raction line arising from the lanes designated by :iller indices (h%l)# K
Ta*le %0.'# Average crystalli crystallite te si,e si,e of CMI 3 determined using *cherrer
e0uation C] C4#C>C 56#?5 >?#>>4
]
1?#1146 C4#1>1>5 >#49
\h%l -#?-4 -#9>9C -#C-?
8rystallite *i,e(nm) C#-->>7 -4 9#C--67 -9 ?#9-1C7 -4
Average 8rystallite *i,e(nm)
C6#-9>?
46
Ta*le %0.0# Average crystallite si,e of CMP 3 determined using *cherrer
e0uation C] C5#1>C9 C4#495C 1#-1? ?1#9?56 ?4#146
]
1C#546?5 1?#??>6 15#65-> C-#9>C4 C?#-9
\h%l -#9>9C 1#1?C? -#?496 -#65C4 -#65C4
8rystallite *i,e(nm) 4#1C67 -9 >#14-9?7 -9 1#645-?7 -4 1#-C>7 -4 1#-57 -4
Average 8rystallite *i,e(nm)
11#>?1?
RESULTS RESULTS AND AN D DISCUSSION DISC USSION
The WR= attern of the samles of both CMI and CMP sho"s no "ell de3ned ea%s! reveals the articles synthesi,ed "as amorhous in nature# The annealed samles of both materials sho" some "ellde3ned ea%s in the the WR= WR= att atter ern! n! co con3r n3rms ms the the crys crystal talli line ne natur nature e of the the sa sam mle les# s#
The The
average crystallite si,es of CMI 3 and CMP 3 "ere calculated from W ray ray di/ra di/ract ctio ion n line line broa broade deni ning ng usin using g *che *cherr rrer er e0ua e0uati tion on## The The aver average age crysta crystalli llite te si,e si,e obtain obtained ed for 8erium 8erium molybd molybdoio oiodat date e heated heated at 3C for' hours(CMI 3) is is '5.K6 n! and that for 8erium molybdohoshate heated at 3C for ' hours(CMP 3) is 11.61 n!.
47
0.3 0.3. SEM SEM #! #!age$ ge$ # #th ED EDA9 The surface morhology of the o"der samles "as characteri,ed characteri,ed by scanning electron microscoe (*7:) Z7@LM7@ Z*:69-# The energy disersive analysis of W rays (7=AW) "as carried out on the samles to ascertain the chemical comosition#
0.3.1. SEM #!age o) CMI
F#g&"e.0.3
0.3.'.
SEM #! #!age o) o) CM CMP
48
F#g&"e.0.5
0.3.0. EDA9 o) CMI
F#g&"e.0.6
0.3.0.
EDA9 o) o) CMP
49
F#g&"e.0. RESULTS RESULTS AND AN D DISCUSSION DISC USSION
The *7: image of the CMI and CMP are reroduced in F#g&"e% 0.3 The mor morho holo logy gy obta obtain ined ed from from the the *7: *7: imag image e indi indica cate tess that that 0.5# The nanoarticles are agglomerated to sherical shae# The 7=AW sectrum of the the samle samle CMI and and CMP are are sho"n sho"n in F#g&"e% 0.6 0.# From the 3gure! it is clear that the reared samle contain no other imurities# The SEM "ith EDA9 sectrum of CMI contains elements such as Ce= Mo= I an O but CMP contains elements such as Ce= Mo= O! and P#
0.5.RECORDIN OF FTIR SPECTRUM OF THE SAMPLES The infrared sectroscoic (R) studies of the samles
CMI=CMI
3= 3 =CM CMP P and CMP 3 "ere maderecorded using er%in 7lmer FTR
*ectro hoto :eter in the "avenumber range 3 and c!-1 by <r disc method#
50
100 90
80
70 8 0 ) 6 4 4 1
60
9 2 ) 7 0 4 1 7 6 ) 6 9 9
50 1 7 ) 2 1 6 1
T +
40
30
5 7 ) 5 3 3 1
5 0 ) 1 8 1 1
5 3 ) 9 7 0 1
20
10
1 6 ) 9 0 8
4 0 ) 8 9 3 3
0
5 0 1 ) 2 ) 2 3 8 4 4 5
*10 4000
3500
3000
2500
2000
1500
1000
500
,avenu'-ers (c'*1"
F#g&"e.0.K.FTIR SPECTRUM OF CMI
100
90
80
70
9 1 ) 3 2 6 1
60
50 T +
40 6 8 ) 2 0 4 3
30
8 3 ) 7 3 1 1
7 1 ) 6 0 6
20
10
0 9 ) 8 3 8
0 *10 4000
3500
3000
2500
2000 ,avenu'-ers ,avenu'-ers (c'*1"
1500
1000
500
51
F#g&"e.0.1.FTIR SPECTRUM OF CMI 3
1 00 90
6 7 ) 1 0 4 1
80 3 2 ) 2 6 3 2
70
60
50
8 2 ) 2 5 4 1
7 5 ) 5 2 6 1
6 7 ) 5 2 9 2
T +
40
2 2 ) 7 2 4 3
30
20
3 6 ) 9 9 7
)
5 4 ) 0 4 5
F#g&"e.0.11.FTIR SPECTRUM OF CMP 4 2 ) 1 5 0 1
10
100 0
1 1 ) 5 1 6
90 *10 4000
3500
3000
2500
80
2000
1500
1000
,avenu'-ers (c'*1"
70 7 1 ) 6 2 6 1
60
50 T +
40 1 6 ) 7 0 4 3
30
2 4 ) 8 4 8
20
5 9 ) 7 3 5
9 4 ) 9 4 9
10 6 2 ) 7 4 0 1
0
0 8 ) 4 1 6
3 8 ) 1 6 5
*10 4000
3500
3000
2500
2000
1500
1000
500
,avenu'-ers (c'*1"
F#g&"e.0.1'.FTIR SPECTRUM OF CMP 3
5 0 0
52
RESULTS RESULTS AND DISCUSSION
The FTIR $/ect"&! of samles CMI and CMI 3 "as reroduced in Figures#0. 0.K. The broad absortion bands in the region 00Kc!-1 !151' c!-1! 0'c!-1 G 15'0 c!-1 is due to the valance vibration of occludedM entraed "ater 1# The bands around K c!-1!30 c!-1=' c!-1 ! and 55 c!-1 corresonds to the intrinsic stretching 1 c!1!0 c!-1 an vibration of the metal "ith oygen atoms 11#The additional "ea% bands and shou should lder erss
inth inthe e sec sectr trum um due due to the the micr micros ostr truc uctu tura rall form format atio ion n of the the
samles# The FTIR $/ect"&! of samles CMP and CMP 3 "as reroduced in Figures#0.11 0.1'. The broad absortion bands in the region 0'6c!-1 !15'3c!-1! 06c!-1 G 15'5 c!-1 is due to the valance vibration of occludedM entraed "ater 1#
The bands around 13 c!-1!6KKc!-1=3 c!-1 ! c!-1!51c!-1 ! 351c! and 306 c!-1 corresonds to the intrinsic stretching stretching vibration of the metal
1
"ith "ith oyge ygen n atoms atoms11#The #The addit additio ional nal "ea% "ea% bands bands and and shou should lder erss
inth inthe e
sectrum due to the microstructural formation of the samles#
0.6.Concl&$#on Nanoarticles of 8erium molybdoiodate and 8erium molybdohoshate "ere reared by the chemical coreciitation method using 7=TA as the organic temlating temlating agent# The as reared reared samles samles "as annealed annealed at 3C for to hour hours# s# The The 9RD /atte"n of the sam samle less of both both CMI and CMP sho" sho"ss no "ell "elld de3 e3ne ned d ea% ea%s! s! revea eveals ls the the art artic icle less synt synthe hesi si,e ,ed d "as "as amorhous amorhous in nature# nature# The annealed annealed samles samles of both both material materialss sho" some "ellde3ned ea%s in the WR= attern! con3rms the crystalline nature of the
53
samle samles# s#
3 and CMP 3 "ere The average average crysta crystalli llite te si,e si,ess of CMI 3
calculated from Wray di/raction line broadening using *cherrer e0uation# The average crystallite si,e of CMI 3 is '5.K6 n! and that for CMP 3 is 11.61 11.61 n!. Th SEM #th #th EDA9 EDA9 se The SEM sectru ctrum m of CMI contains
elem elemen ents ts such such as Ce= Mo= O an and I but ! *7: "ith 7=AW sectrum 8: contains elements such as Ce= Mo= P and O# From the *7: *7: image image of both both samles reveals that the articles are agglomerated into sherical shaes and the as reared samles of 8:and 8: contains no other imurities# The FTIR S/ect"&! of CMI=CMI 3=CMP CMP 3 "ere recored and the bands "ere identi3ed#
0.. Re)e"ence 1#
$ +leiter! "rog+Mater+ci+ 00 (1949)11(#
C#
$ +leiter* 2!+Mater (199C) (199C)/)/+
#
8 *uryanarayana! B%ll+Mater+16 (199?)(0)#
?#
: :o3tt! $ Hali and A 7insenberg! 7insenbe rg! Che+Mater+1 (1994) 01#
5#
L rus! 3+"hys+Che+oli!s#3K (1994) /.9#
6#
ing ;hang! u Fang! *han Qang! *huya Lin! 3+Cis+Elseier ! '6'(C--?)!
(1-(1. #
>#
#ramani%! B%ll+Mater+ci #1 (1995)49#
4# $arol
54
1-#
;a"arch : F : and 7
,C--C) )#
11#
*#$afner! ;eit#
