Capacitors and Piezoelectric Devices
2 Capacitors and Piezoelectric Devices
🧭 Overview
🧠 One-sentence thesis
Capacitors, piezoelectric devices, pyroelectric devices, and electro-optic devices all rely on establishing material polarization in a dielectric layer, and understanding how capacitors work through material polarization provides insight into these energy conversion devices.
📌 Key points (3–5)
- Core mechanism: All these devices involve establishing a material polarization (charge separation) throughout a dielectric material.
- What makes piezoelectric devices special: Mechanical strain causes material polarization, enabling two-way energy conversion between mechanical energy and electricity.
- Why start with capacitors: Capacitors are familiar energy storage devices whose operation depends on material polarization; understanding them clarifies piezoelectric, pyroelectric, and electro-optic devices.
- Common confusion: Capacitance C is not just a constant—it depends on the permittivity of the dielectric material, which stores energy by polarizing when the capacitor charges.
- Crystal structure matters: Only 21 of 32 crystal point groups (those without inversion symmetry) can be piezoelectric; the effect depends on crystallographic orientation.
🔋 How capacitors store energy through material polarization
🔋 Basic capacitor relationships
- In introductory circuits, a capacitor is described by i = C dv/dt where C is just a constant.
- The charge-voltage relationship is Q = Cv where Q is charge in coulombs, v is voltage, C is capacitance in farads.
- Energy stored: E = (1/2)Cv² = (1/2)Qv.
- To go beyond this simple model and understand different capacitor types, we need to examine material polarization.
🧲 Material polarization defined
Material polarization: charge separation throughout a material when an external voltage is applied across an insulator.
- More precisely, material polarization P (in C/m²) is defined as the difference between the electric field in the material D and the field that would be present in free space ε₀E:
- P = D - ε₀E or P = (ε - ε₀)E
- Two electric field parameters exist: displacement flux density D and electric field intensity E, related by D = εE.
- Why two parameters? It separates the description of the electric field inside a material from the field in free space.
- Similarly, magnetic fields use two parameters: magnetic field intensity H and magnetic flux density B.
⚡ How dielectric materials increase energy storage
- For a parallel plate capacitor: C = εA / d_thick where A is plate area, d_thick is distance between plates, ε is permittivity.
- A vacuum-filled capacitor has ε = ε₀ (permittivity of free space).
- Key insight: When you replace vacuum with a dielectric (ε > ε₀), capacitance becomes larger because the dielectric material changes as the capacitor charges.
- What happens during charging:
- In an insulator, electrons are bound to atoms and cannot flow as current.
- Instead, electrons move slightly with respect to their nuclei while staying bound.
- This displacement balances charges on the plates, storing more energy for a given voltage.
- We say this process induces electric dipoles.
- The larger the permittivity ε, the more energy the material can store by polarizing.
- Example: Tantalum dioxide (Ta₂O₅) has ε = 25ε₀, so it stores 25 times the energy of an air-filled capacitor of the same size at the same voltage.
📊 Permittivity and related measures
All these describe the ability of a material to store energy in the electric field:
| Measure | Symbol | Definition | Notes |
|---|---|---|---|
| Permittivity | ε | Material property | Units: F/m |
| Relative permittivity | εᵣ | εᵣ = ε/ε₀ | Unitless |
| Electric susceptibility | χₑ | χₑ = ε/ε₀ - 1 | Unitless |
| Index of refraction | n | n = c/|v| = speed of light in free space / speed in material | Unitless, n > 1; for good insulators with μ = μ₀: n = √εᵣ |
- Material polarization can be written: P = (εᵣ - 1)ε₀E = ε₀χₑE
- Table 2.1 lists relative permittivities: vacuum (1.0), Teflon (2.1), SiO₂ (3.5), Si (11.8), Ta₂O₅ (24), BaSrTiO₃ (300), PbTe (360).
🔷 Anisotropic materials
- In some crystalline materials, permittivity depends on direction.
- A voltage along one crystallographic axis may induce charge separation more easily than along a different axis.
- Such materials are called anisotropic; permittivity is better described by a 3×3 matrix than a scalar.
- Example (Fig. 2.1): atoms with nuclei (black circles) and electron clouds (gray circles); when an electric field is applied in one direction, electrons displace relative to nuclei; the external field needed for the same displacement differs in different crystallographic directions.
🔧 Capacitor properties and types
🔧 Key selection parameters
- Capacitance and maximum voltage: first two measures to consider; exceeding maximum voltage can damage the capacitor.
- Fig. 2.2 shows ranges for different types:
- Electrolytic: 10⁻⁷ to 1 F, 1 to 1000 V max.
- Ceramic: 10⁻¹³ to 5·10⁻⁴ F, 1 to 50,000 V max.
🌡️ Other important factors
- Temperature stability: ideally capacitance is independent of temperature; ceramic and electrolytic capacitors are more sensitive than polymer or vacuum capacitors.
- Accuracy/precision: capacitors have tolerances (e.g., ±5%, ±10%), like resistors.
- Equivalent series resistance (ESR): all materials have some resistivity; model a physical capacitor as an ideal capacitor in series with an ideal resistor.
- Leakage: how well a capacitor retains stored charge when disconnected; ideal capacitor has no leakage; electrolytic capacitors have larger leakage.
- Lifetime: ideal capacitor operates for decades; electrolytic capacitors are not designed for long lifetimes.
- Other factors: cost, availability, size, frequency response.
🧱 Capacitor types by dielectric material
| Type | Advantages | Disadvantages | Notes |
|---|---|---|---|
| Ceramic | Small, cheap, readily available; tolerate large voltages; low ESR | Small capacitance, poor accuracy, poor temperature stability, moderate leakage; can cause voltage spikes; some are piezoelectric (vibration → noise) | |
| Mica | Good accuracy, small leakage | Mica is a flaky mineral with layered structure; can make very thin dielectric layers; natural forms include biotite and muscovite KAl₂(AlSi₃O₁₀)(OH)₂ | |
| Polymer | Good accuracy, temperature stability, leakage | Types: polystyrene, polycarbonate, polyester, polypropylene, Teflon, mylar | |
| Vacuum | Very low leakage | Used in high-voltage or very-low-leakage applications | |
| Oil (liquid dielectric) | Similar applications to vacuum | ||
| Electrolytic | Small device can have large capacitance | Poor accuracy, temperature stability, leakage; finite lifetime (liquid degrades); polarized (positive/negative terminals; reversing voltage destroys capacitor) | Dielectric is solid + liquid electrolyte; initial voltage application chemically creates oxide layer (the dielectric) |
- Electrolyte: a liquid through which some charges flow more easily than others.
- Don't confuse: "polarized" capacitor (has positive/negative terminals) vs. "material polarization" (charge separation in dielectric).
⚙️ Piezoelectric devices: mechanical stress induces polarization
⚙️ Core principle
- Can we induce material polarization without applying a voltage? Yes—this creates an energy conversion device.
- In piezoelectric devices, mechanical stress causes material polarization.
- When stress is exerted, valence electrons are displaced, but nuclei and other electrons do not move.
- When stress is released, material polarization goes away.
- Don't confuse with permanent crystal structure change (e.g., coal → diamond under high pressure/temperature, or shot peening of steel); piezoelectricity requires little energy and is reversible.
📐 Piezoelectric strain constant
- Material polarization in a piezoelectric insulator:
- P = D - ε₀E + dς
- d is the piezoelectric strain constant in m/V.
- ς is stress in pascals (Pa = J/m³ = N/m²).
- For many materials, d is zero or very small.
- Barium titanate has relatively large d ≈ 3·10⁻¹⁰ m/V.
- Mechanical strain (unitless) vs. stress (units: Pa):
- Without external electric field: strain = (1 / Young's elastic modulus) · stress.
- With electric field: strain = (1 / Young's elastic modulus) · stress + E · d.
- Energy stored under stress ς: E = |ς| · A · l · η_eff where A is cross-sectional area (m²), l is deformation (m), η_eff is efficiency.
- Bigger devices, more deformation, or larger piezoelectric constants → more energy stored.
🔬 Nonlinear piezoelectricity
- The linear relationship (P proportional to ς) describes many materials but not all.
- For other piezoelectric crystals, polarization is proportional to the square of stress:
- |P| = |D| - ε₀|E| + d|ς| + d_quad|ς|²
- d_quad is another piezoelectric strain constant.
- Some materials need terms with higher powers of stress.
🔮 Crystal structure and piezoelectricity
🔮 Describing crystal structures
- Crystalline materials: atoms arranged periodically; composed of elements (e.g., Si) or compounds (e.g., NaCl).
- Two components describe atom arrangement: lattice and basis.
- Lattice: a periodic array of points in space; specified by n lattice vectors for n-dimensional lattice.
- For 3D: three vectors a₁, a₂, a₃; travel integer multiples of these vectors to get from one lattice point to any other.
- Primitive lattice vectors: as short as possible.
- Cell: area (2D) or volume (3D) formed by lattice vectors.
- Primitive cell: smallest possible repeating unit describing a lattice (formed by primitive lattice vectors).
- Crystal basis: arrangement of one or more atoms attached to every lattice point.
- Crystal structure: lattice + crystal basis together.
- Example (Fig. 2.5): 2D lattice with two primitive vectors; basis has two atoms of one type and one of another.
🧊 Bravais lattices and crystal systems
- 14 possible 3D lattice types called Bravais lattices.
- Examples (Fig. 2.6): simple cubic, body centered cubic, face centered cubic, asymmetric triclinic.
- Simple cubic: all angles between nearest neighbors are right angles; all nearest-neighbor lengths equal.
- Asymmetric triclinic: no right angles; no equal nearest-neighbor lengths.
- Primitive cell angles labeled α, β, γ; side lengths labeled a, b, c (Fig. 2.9).
- Crystal system: classification based on angles and lengths of primitive cell (e.g., triclinic, monoclinic, orthorhombic, tetragonal, trigonal, hexagonal, cubic/isometric).
- Example crystal structures:
- Sodium chloride: face centered cubic lattice + basis of one Na and one Cl atom.
- Silicon: diamond structure = face centered cubic lattice + basis of two Si atoms at (0,0,0) and (l/4, l/4, l/4).
- Diamond structure: C, Si, Ge, Sn with cell lengths l = 0.356, 0.543, 0.565, 0.646 nm respectively.
🔑 Crystal point groups and symmetry
- Cannot list all possible crystal structures (infinite), but they are classified by symmetries.
- Possible symmetry operations: 2-fold, 3-fold, 4-fold, 6-fold rotations; horizontal/vertical mirror planes; inversion.
- Crystal point groups: 32 possible groups based on symmetry elements.
- Two labeling systems:
- Hermann-Mauguin notation (1930s): used by chemists, mineralogists, some physicists.
- Schoenies notation (1891): used by mathematicians, spectroscopists, other physicists.
- Table 2.2 lists all 32 crystal point groups with both notations, crystal system, primitive cell angles/lengths, and whether materials can be piezoelectric, pyroelectric, or Pockels electro-optic.
- Crystal space groups (230 total): based on symmetry transformations including translations + rotations/mirror planes; not discussed further in this text.
🪞 Inversion symmetry
- Inversion operation: in 3D, a shape has inversion symmetry if it is identical when rotated 180° and inverted through the origin.
- Draw vector V from center to any surface point; if shape has inversion symmetry, point at -V is also on surface.
- Example (Fig. 2.8): left shape has inversion symmetry; right shape does not.
- Center of symmetry: crystal structure with inversion symmetry.
- Noncentrosymmetric: no inversion symmetry.
- 21 of 32 point groups have no center of symmetry (Table 2.2, sixth column).
- 20 of these 21 groups have a polar axis: some axis with different forms on opposite ends.
- Mechanically stressing along the polar axis → different charge buildup on different sides.
- Dielectric crystalline materials in any of these 21 noncentrosymmetric groups are piezoelectric.
⚠️ Practical considerations
- Even if crystal structure has no inversion symmetry, the piezoelectric effect and strain coefficient d may be too small to measure.
- Effect may only occur for stress along particular axes, not arbitrary orientations.
- Only one crystal point group (asymmetric triclinic) allows random stress to produce material polarization.
- For all other groups, only stresses along certain axes produce polarization.
- In most crystals, stress along one axis produces different polarization than the same stress along a different axis.
- More accurate description: piezoelectric strain coefficient is a 3×6 matrix with elements d_ik = (∂strain along k / ∂electric field along i) at given stress.
- Electric field has x, y, z components; stress can be along xx, xy, xz, yy, yz, or zz directions.
🌀 Ferroelectricity and poling
🌀 Piezoelectricity in non-crystalline materials
- Previous section discussed crystals; cannot define crystal structure for amorphous materials.
- But piezoelectric devices can be made from polycrystalline and amorphous materials.
- In dielectrics, external electric field induces material polarization (electrons/nuclei displace slightly).
- Charge buildups (electric dipoles) induce additional electric fields (Coulomb's law).
- Secondary effect: once one atom polarizes, nearby atoms polarize.
- Small regions of the same material polarization are called electrical domains.
🌀 Ferroelectric effect
- In certain dielectrics, external mechanical stress induces local material polarization.
- This polarization induces polarization in nearby atoms, forming electrical domains.
- Ferroelectricity: nonlinear process where one atom's polarization induces polarization in nearby atoms, forming domains.
- Can occur in crystalline, amorphous, or polycrystalline materials.
- For non-crystalline materials, the effect is necessarily nonlinear (not well described by linear equations).
- Ferroelectric materials can be ferroelectric piezoelectric, ferroelectric pyroelectric, or ferroelectric electro-optic (next chapter).
- Curie temperature: for many ferroelectric materials, effects occur only below this temperature; heating above it removes the ferroelectric effect.
- Hysteresis: material polarization depends on past history; ferroelectric materials may have polarization even without external stress or field if energy was previously applied.
🧲 Etymology and analogy
- "Ferro-" means iron, but most ferroelectric materials do not contain iron, and most iron-containing materials are not ferroelectric.
- Analogy to ferromagnetic: some iron-containing materials are ferromagnetic.
- External magnetic field → internal magnetic field in material.
- Can have permanent magnetic dipole without applied field.
- Electric dipole modeled as pair of charges; magnetic dipole modeled as small current loop.
- Ferromagnetic materials exhibit hysteresis and have magnetic domains with aligned dipoles.
🔌 Poling process
- Initially: piezoelectric ferroelectric material has randomly aligned electrical domains and no net polarization; not yet piezoelectric or ferroelectric.
- Poling: process of causing a material to exhibit piezoelectricity and ferroelectricity.
- How to pole: place material in a strong external electric field (e.g., across battery poles—hence the term).
- Poling does not change atomic structure (amorphous material remains amorphous).
- During poling, electrical domains form and remain when external field is removed.
- After poling: material may have net polarization throughout; is now piezoelectric and ferroelectric (external stress induces polarization locally and throughout).
- Electret: material that is piezoelectric due to this type of poling.
🛠️ Piezoelectric materials and applications
🛠️ What makes a good piezoelectric material
- Electrical insulator: when voltage is applied across a conductor, valence electrons are removed from atoms, so no material polarization accumulates.
- Large piezoelectric strain constant: d is so small it cannot be detected in many crystals from the 21 known piezoelectric point groups; zero in other groups.
- Not brittle: should withstand repeated stressing without permanent damage.
- Thermal properties may also be important.
- No single material is best for all applications.
🧪 Common piezoelectric materials
| Material | Notes |
|---|---|
| Quartz (crystalline SiO₂) | First material studied (Pierre and Jacques Curie, 1880s); used in crystal oscillators today |
| Lead zirconium titanate | Relatively high piezoelectric strain constant |
| Polyvinyldenfluoride (polymer) | Flexibility; withstands repeated stress without damage |
| Barium titanate (BaTiO₃) | Relatively large d ≈ 3·10⁻¹⁰ m/V |
| Lithium niobate, tourmaline, Rochelle salt | Also studied |
- Manufacturers often do not label whether devices are crystalline, amorphous, or polycrystalline.
- Polycrystalline/amorphous advantages: easier to make into different shapes (cylinders, spheres).
- Polycrystalline/amorphous disadvantages: often lower melting temperatures, higher temperature expansion coefficients, more brittle.
- Crystalline advantages (e.g., quartz): harder, higher melting temperature.
🔌 Electrical component applications
- Oscillators: voltage applied → material bends; voltage released → springs back at natural resonant frequency; integrated with feedback circuit → precise frequency oscillations; often made from crystalline quartz.
- Piezoelectric transformers: used in cold cathode fluorescent lamps (LCD panel backlights); require ~1000 V to turn on, hundreds of volts during use; much smaller than magnetic transformers (small enough for PCB mounting).
- Traditional transformer: AC electricity → magnetic energy → AC electricity at different voltage (pair of coils).
- Piezoelectric transformer: AC electricity → mechanical vibrations → AC electricity at different voltage.
- Energy conserved: high voltage with low current.
- Example (Fig. 2.10): converts 8-14 V input to up to 2 kV output.
- Small components (Fig. 2.11): microphones, ultrasonic transmitters/receivers, vibration sensors, oscillator crystals.
⚡ Energy harvesting and sensors
- Efficiency: hard to discuss (different assumptions); commercial devices often 6% or less.
- Due to low efficiency, many devices used as sensors.
- Despite low efficiency, some used for energy harvesting:
- Train station embedded devices in platforms to generate electricity.
- Convert energy from fluid motion or wind directly to electricity.
🏥 Biomedical applications
- Quartz: piezoelectric, durable, readily available, nontoxic.
- Devices designed for outside and inside the body.
- Sensors: monitor knees/joints; ultrasonic imaging (generate and detect ultrasonic vibrations).
- Power sources: artificial hearts, pacemakers, other devices limited by battery technology; piezoelectric generators have no moving parts, avoid battery changes.
- Physical activity types: continuous (breathing) or discontinuous (walking); both can be energy sources.
- Power requirements vary: artificial heart ~8 W, pacemaker ~few microwatts.
- Examples: device in artificial knee produced 0.85 mW; device in shoe generated 8.4 mW from walking.
🔊 Other applications
- Imaging systems: sonar (WWI military development for detecting boats/submarines; today: detect fish, measure water depth, analyze circuits, detect imperfections/cracks in steel/welds).
- Buttons and keyboards: piezoelectric sensors.
- Accelerometers: measure acceleration.
- Pipe flow measurement.
- Speakers, microphones, buzzers: audio and ultrasonic frequencies.
- Ultrasonic emulsification: dyes, paints, food products (e.g., peanut butter).
- Barbecue grill ignitions: mechanical stress induces electric spark.