Introduction
Piezoelectric materials have been largely used in transducers since the last century [1]. Moreover, many piezoelectric materials have been synthesized by blending two compounds in appropriate proportions to tailor the properties of the so formed materials to suit the application [1]. After the discovery of naturally occurring piezoelectric materials, perovskite structured piezo-ceramics have been synthesized with far better piezoelectric constants and mechanical stability [1]. Currently for MEMS, thin films of compounds like Zinc Oxide, PZT, and Aluminium Nitride are being produced which have an enhanced performance due to the selected process parameters during their manufacturing [2]. Piezoelectric materials also are manufactured as a composite with the help of a synergic effect of a polymer and its ceramic phase to get the best fit of intermediate properties [3]. This paper discusses the trends in piezoelectric materials and their piezoelectric properties used as thin films with their application in MEMS devices.
Naturally Occuring Materials
The most common naturally occurring materials showing piezoelectricity are Quartz, Berlinite, Sucrose, Rochelle Salt, Cinnabar, Topaz and the Tourmaline group. Quartz is the first piezoelectric material to be found which has a crystalline structure made up of a continuous framework of SiO4 silicon-oxygen tetrahedral with each oxygen atom being shared by two tetrahedral. The overall Quartz structure is an intermingle of two helices with different handedness with each SiO4 being a member of the above mentioned helices. Thus overall the structure is not polar unless subjected to a pressure which results in a polarized structure.
The reported values of naturally occurring quartz crystal owing to its piezo-electric coefficients and dielectric properties are given below in Table 1, where ‘K’ refers to coupling constant.
Table 1: Piezoelectric Properties of Quartz [1]
Cut
|
K
|
Piezo-Constant
|
X
|
-0.09
|
2.3 X 10-12 C/N
|
Y
|
-0.14
|
-4.6 X 10-12 C/N
|
AT
|
-0.08
|
-3.4 X 10-12 C/N
|
AC
|
-0.10
|
-3.7 X 10-12 C/N
|
BC
|
-0.04
|
-0.9 X 10-12 C/N
|
Cut described in the above Table: X (Parallel to YZ Plane),Y (Parallel to XZ Plane),AT(35°15´ with Z axis),AC(31° with Z axis),BC(-59° with Z axis)
However due to a serious dearth of naturally occurring materials, quartz is also being synthesized artificially with the same physical, electric and chemical properties but the Quartz wafer is cut at different angles making them suitable for various applications according to the frequencies it can work with as shown in the Table above[1].
Quartz Crystal have also been deposited on silicon substrate as a thin film to be used as FBAR(Film Bulk Acoustic Resonator) working in frequencies close to 200 MHz with a coupling factor close to 0.004 and thermal expansion coefficient being equal to 26 ppm /°C[4].Quartz crystal has also been used as a part of MEMS motion sensing devices like the accelerometer and as a resonator[5].Quartz has been inculcated in temperature sensor, as the frequency of the resonator is subject to change with temperature and precise calculations are possible with the temperature coefficient of frequency being 75 ppm/°C[5]. Quartz is also been seen as an alternative to silicon in MEMS inertial sensors, as an accelerometer using fluoride based chemical etchant and chromium gold thin foil as a masking agent in Quartz (using electrodes to induce vibration) has been fabricated yielding ‘Q’ values of 7000-8000[6].It has also found application as a transducer( a Quartz tuning fork ) to be used for photo-acoustic detection of trace gases with the reported sensitivity of 5.4 X 10-9 cm-1 W/(Hz)1/2[7].
Rochelle Salt (NaKC4H4O6-4H2O), is one oldest material showing ferroelectricity between the two Curie temperatures Tc1=255 K [8] and Tc2=297 K [8] showing orthorhombic structure in the paraelectric phase and the monoclinic structure in the ferroelectric phase. It has a very low decomposition temperature equal to 55°C [8].Due to its bad behaviour to change in temperature and being water soluble it is not currently being used and also has not been fabricated as a thin film. The known piezoelectric coefficients (‘d’ and ‘g’) of Rochelle Salt obtained with the help of X-ray multiple diffraction are given in Table 2,
Table 2: Piezoelectric Properties of Rochelle Salt [9]
d21
|
7.0 X 10-10 C/N
|
d22
|
2.2 X 10-9 C/N
|
d23
|
2.1 X 10-9 C/N
|
d25
|
3.7 X 10-11 C/N
|
Along with these naturally occurring materials, organic substances like tendon, silk, wood and dentin are also known to be piezoelectric materials.
Piezoceramics
Piezoceramics first came into being due to high dielectric constant observed in BaTiO3 due to its ferroelectricity (a phenomena in which a polar state exists before the application of pressure).BaTiO3 was the first piezoelectric ceramic developed which namely exists in two basic structures a perovskitic form which is ferroelectric at temperatures below 1460°C and a hexagonal form which is stable above 1460°C [10- Pg 53].
Table 3: Comparative Piezoelectric Properties of BaTiO3 ceramic and single crystal [10- Pg 74]
|
Single Crystal
|
Ceramic
|
k15
|
0.570
|
0.476
|
k31
|
0.315
|
0.208
|
k33
|
0.560
|
0.493
|
d15
|
392 X 10-12 C/N
|
270 X 10-12 C/N
|
d33
|
85.6 X 10-12 C/N
|
191 X 10-12 C/N
|
d31
|
-34.5 X 10-12 C/N
|
-79 X 10-12 C/N
|
g31
|
-23.0 X 10-3Vm/N
|
-4.7 X 10-3Vm/N
|
g33
|
57.5 X 10-3Vm/N
|
11.4 X 10-3Vm/N
|
g15
|
15.2 X 10-3Vm/N
|
18.8 X 10-3Vm/N
|
Compounds based originally on BaTiO3 like BaTi 0.90Ga 0.05Nb 0.05 O3 (BTGN) and Ba0.60Sr0.40TiO3 (BST) have also found way in microwave applications at desired frequencies [11].Thin films of BaTiO3 have been used for energy conversion after having deposited on a flexible substrate and then used for electrical power generation by bending the corresponding with the nano-generator producing voltage up to 1V[12].Most of the known piezoceramics have a perovskitic structure in which larger cations occupy the corner of the cubic unit cell while smaller cations are at the body centre and oxygen atoms at the centre of each face[10-Pg 49].By adding combinations of atoms to BaTiO3 that are oppositely deviating valency, such as K+1 or Li+1 replacing Ba+2, Fe+3 + Nb+5 replacing 2Ti+4, Na+1, Nb+5 replacing Ba+2 + Ti+4 extensive solid solutions are possible with modified ferroelectricty and a decrease in Curie point sharply [10-Pg107-108].Some additives have also been used to improve the dielectric strength of BaTiO3 like Nb2O5 , Ta2O5, NaNbO3, NaTaO3, CuO , In2O3,La2O3 and some larger rare earths like CeO2,Fe2O3 and NiO [10-Pg 104].Aluminium Nitride (AlN) and ZnO are the materials widely used as piezoelectric thin films for MEMS[13-Pg40]. Some of the lead based piezoceramics like PZT (lead zirconium titanate) have also been used as thin films in cantilever beams, diaphragms for optical-MEMS(mirrors, scanners) and have also formed a part of RF-MEMS(Antennas, Resonators, Microwave Switches), Power-MEMS and Bio-MEMS[13-Pg 477-478]. Rare earth substituted thin films of BiFeO3 have also been investigated with adulterations of Nd3+ and La3+ [14].
Many other lead based compounds were synthesized following structural analogy with BaTiO3 like PbZrO3, PbTiO3, PbHfO3, PbSnO3[10- Pg 115-133].PbTiO3 has a distorted perovskitic structure [10-Pg115].PbTiO3 and Pb1-xLaxTi1-x/4O3(PLT) thin films grown on MgO substrate have been successfully integrated in IR sensors which have shown better pyroelectric, piezoelectric and ferroelectric properties along with good response time [15].Also BaTiO3 is adulterated with isovalent cations like Ca+2, Sr+2 and Cd+2 to lower the Curie point and to diminish the tetragonal distortion [10-Pg91-96].Similarly when BaTiO3 as poled with Sr+2 a linear reduction in Curie point was seen [10-Pg94]. Some of the other known solid solutions of PbTiO3 are PbTiO3-LaAlO3, PbTiO3—LaFeO3,PbTiO3-Pb(Fe0.5Ta0.5)O3, PbTiO3-PbMg0.5W0.5O3, PbTiO3-Pb(Fe0.5Nb0.5)O3, PbTiO3-Pb(Mg1/3Nb2/3)O3,PbTiO3-Pb(Zn1/3Nb2/3)O3, PbTiO3-KNbO3,PbTiO3-BiMnO3,PbTiO3-K1/2Bi1/2TiO3 [10-Pg151-154].Most of the above mentioned solid solutions operate near the Morphotropic Phase Boundary which is related to percentage composition where two lattice structures co-exist leading to the elevation of piezoelectric properties. Some of the other lead based ternary systems with their characteristics are given in Table 4 below,
Table 4: Characteristics of ternary systems [13-Pg 100]
Pb (Mn1/3Sb2/3)O3
|
High Qm (Quality factor), Large k
|
Pb (Sn1/3Sb2/3)O3
|
High Qm, (Quality factor), Large k
|
Pb (Mg1/3Nb2/3)O3
|
High Qm(Quality factor)
|
Pb (Nb1/2Sb1/2)O3
|
Thermal Stability
|
Pb (Ni1/3Nb2/3)O3
|
Large d constant
|
Pb (Zn1/3Nb2/3)O3
|
Large d constant
|
With a view to reduce the environmental damage to the earth, bismuth based ternary compounds were synthesized like (Bi1/2K1/2)TiO3, (Bi1/2Li1/2)TiO3 with properties comparable to lead based ternary compounds[13-Pg130]. Antiferroelectricity is the presence of switchable polar states above Curie temperature which was first seen in Rochelle Salt and later in PbZrO3 [8,10].There are several additives to PbZrO3 that in small quantities stabilize either a rhombohedral ferroelectric phase or a tetragonal antiferroelectric phase below Curie Point[10- Pg127-130].PbSnO3 is also ferroelectric but unstable thus popularly exists in a binary state of (Pb,Ba)SnO3[10-Pg 131].Pb HfO3 is isostructural to PbZrO3 and also anti-ferroelectric for a tetragonal phase between 163°C and 215°C [10-Pg 132].
Popular PZT solid solutions are Pb(Ti0.48Zr0.52)O3 and (Pb0.94Sr0.06)(Ti0.47Zr0.53)O3 and have properties as tabulated in Table 5 and 6,
Table 5: Piezoelectric Constants of Pb(Ti0.48Zr0.52)O3 [10-Pg 146]
k31
|
0.31
|
k33
|
0.67
|
d31
|
-93 X 10-12 C/N
|
d33
|
223 X 10-12 C/N
|
d15
|
494 X 10-12 C/N
|
g31
|
-11.1 X 10-3 Vm/N
|
g33
|
26.1 X 10-3 Vm/N
|
g15
|
39.4 X 10-3 Vm/N
|
Table 6: Piezoelectric Constants of (Pb0.94Sr0.06)(Ti0.47Zr0.53)O3 [10-Pg 146 ]
k31
|
0.33
|
k33
|
0.70
|
d31
|
-123 X 10-12 C/N
|
d33
|
289 X 10-12 C/N
|
d15
|
494 X 10-12 C/N
|
g31
|
-14.5 X 10-3 Vm/N
|
g33
|
34.5 X 10-3 Vm/N
|
g15
|
47.2 X 10-3 Vm/N
|
PZT is at the heart of various applications due to the attributes given in Table 7 below,
Table 7: Applications and Properties [13-Pg 95]
Application
|
Attributes
|
Injet Actuator
|
Large d constant;Stability
|
Fuel Injector
|
Large d constant
|
Buzzer
|
Large d constant
|
Shock Sensor
|
Large d & g constant
|
Ultrasonic Motor
|
High Qm(Quality factor)
|
Gyroscope
|
High Qm(Quality factor)
|
Filter
|
Thermal Stability
|
Ultrasonic motors have also been fabricated in MEMS using PZT thin films but however its actuation requires large current compared to electric static motors [16].Due to its ferroelectric nature it has also found use in NVRAMs due to its switchable configurations being used as memory states and in SAW devices and pyroelectric sensors [17]. The other known solid solutions of Pb(Hf,Sn,Ti,Zr)O3 are (Pb,Ba)(Ti,Sn)O3,Pb(Hf,Ti)O3 and Pb(Hf,Sn,Ti)O3[10-Pg 170-175].
NaNbO3, KNbO3, NaTaO3 and KTaO3 also have a perovskitic structure and are reported to be ferroelectric [10-Pg 185].KNbO3 has a great similarity with BaTiO3 having four polymorphic forms namely cubic, tetragonal, orthorhombic and rhombohedral with a Curie temperature of 435°C[10-Pg 186-187].Solid solutions in niobates and tantalates include (Na,K)NbO3 (with Na0.5K0.5NbO3 showing the highest piezoelectric coupling coefficient)[10-Pg 194], (Na,Cd)NbO3 (with Na0.75Cd0.125NbO3 showing optimum piezoelectric properties)[10-Pg 197], (Na,Pb)NbO3, NaTaO3-NaNbO3, KTaO3-KNbO3 , AgNbO3-AgTaO3 [10- Pg 197-200]. LiNbO3 and LiTaO3 are being used extensively as electro-optic, photorefractive, and non-linear optical crystals and being poled ferroelectrics they are also used in memory storage [18].Some of the other known compounds with their Curie temperatures are given below in Table 8,
Table 8: Compounds and their Curie Temperatures [10-Pg 200-201]
Compound
|
Curie Temperature
|
CsGeCl3
|
155°C
|
WO3
|
-50°C
|
CdTiO3
|
-183°C
|
BiNaTi2O6
|
320°C
|
BiKTi2O6
|
380°C
|
Pb2FeNbO6
|
112°C
|
Pb2FeTaO6
|
-30°C
|
Pb2YbNbO6
|
300°C
|
Pb2YbTaO6
|
285°C
|
Pb2LuNbO6
|
270°C
|
Pb2LuTaO6
|
278°C
|
Pb2ScNbO6
|
90°C
|
Pb2ScTaO6
|
26°C
|
Pb2MgWO6
|
39°C
|
Pb3MgNb2O9
|
-10°C
|
Pb3MgTa2O9
|
-98°C
|
Pb3CoNb2O9
|
-70°C
|
Pb3CoTa2O9
|
-140°C
|
Pb3NiNb2O9
|
-120°C
|
Pb3NiTa2O9
|
-196°C
|
Pb3ZnNb2O9
|
140°C
|
Pb3Fe2WO9
|
-90°C
|
Pb2CdWO6
|
130°C -240°C
|
BiFeO3
|
850°C
|
PbNb2O6 was the first ever oxide type non-perovskite ferroelectric discovered (Tc = 570°C)[10-Pg 214] having a potassium tungsten bronze structure. Some other examples showing similar structure are PbTa2O6 (Tc = 260°C[10-Pg 217]), BaNb2O6, SrNb2O6 and K1.2Li0.8Nb2O6.Solid solutions of the above compounds also do exist like PbNb2O6– PbTa2O6, PbNb2O6– BaNb2O6, PbNb2O6-SrNb2O6[10-Pg 218-220].Some of the ferroelectrics also have a distorted pyrochlore structure like Cd2Nb2O7 and Sr2Ta2O7 are ferroelectric with Curie points of -88°C [10-Pg226] and -80°C [10-Pg 226].The Bismuth Layered Structures are characterized weak piezoelectric effects. The structure consists of layers of Bi2O2+ separating two perovskite structures in one dimension while the structure spreading infinitely in the other two directions [10-Pg226]. The general formula is described by Bi2Ax-1BxO3x+3[10-Pg 226].Known Bismuth layered structured compounds are Bi3TiNbO9, BiTiTaO9, Bi2PbNb2O9, Bi2CaNb2O9, Bi2PbTa2O9,Bi2CaNb2O9, Bi2CaTa2O9, Bi2SrNb2O9, Bi2SrTa2O9, Bi2BaNb2O9, Bi2BaTa2O9[10-Pg224]. Relaxor ferroelectrics have a diffuse, frequency dependent permittivity. Some examples of relaxor ferroelectrics are PMN-PT, PZN-PT and PIN-PT[10-Pg206].As the properties of relaxor ferroelectrics can be ‘tuned’ it is used to sense acoustic waves of various frequencies and depth profiles [19].
Polymers
Piezoelectricity was first seen in PVDF in 1969[20] and later was discovered in copolymers of vinylidene fluoride, trifluoroethylene, vinyl-cyanide, vinylacetate and nylons along with various bio-polymers [20]. Piezoelectric constants (in the shear direction) of various bio-polymers have been given below in Table 9,
Table 9: Piezoelectric Properties of Natural Bio polymers [20]
Wood
|
0.1 pC/N
|
Ramie
|
0.2 pC/N
|
Crab Shell
|
0.2 pC/N
|
Lobster apoderme
|
1.5 pC/N
|
Starch
|
2.0 pC/N
|
Bone
|
0.2 pC/N
|
Tendon
|
2.0 pC/N
|
Skin
|
0.2 pC/N
|
Wool
|
0.1 pC/N
|
Horn
|
1.8 pC/N
|
Salmon DNA
|
0.07 pC/N
|
Similarly poled films of PVDF were tested for their piezoelectric constants and large piezoelectricity was seen (d31=20pC/N;d32=1.5pC/N;d33=32pC/N;d15=-27pC/N and d24=-23pC/N) [21].A film of copolymer vinylidene cyanide and vinyl acetate was poled at 150°C and a piezoelectric constant of 5pC/N was observed [22]. PVDF has a glass transition temperature of -35°C and is found to be partially crystalline. Thin films of PVDF also have shown superior piezoelectric constant of 6-7pC/N [13-Pg14].Thin films of P(VDF/TrFE) with a molar ratio (75/25) have also been synthesized with thickness ranging 5-100 micrometers [20]. Thin films of polyurethane have also been synthesized using vapour deposition methods [20]. PVDF has been used extensively in ultrasonic imaging as a transducer with operating frequencies of 60-85 kHz [23].Piezoelectric polymers like PVDF having low permittivity, low thermal conductivity and flexibility with low acoustic loss are used extensively in shock sensors, vibration control and tactile sensors [24].
Conclusion
From literature a categorization of natural and artificial piezoelectric materials was done and their piezoelectric properties and constants were enlisted. Similarly it was shown that they could also be used for thin film applications in MEMS devices.
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