Technical articles

From Barium Titanate Dielectrics to Multilayer Ceramic Capacitors: Dielectric Properties and Experimental Evaluation of Barium Titanate-Based Ceramics

Introduction

 

Barium titanate is a typical perovskite oxide and an important base material for high-permittivity ceramic capacitor dielectrics. Its core value does not lie in light absorption, but in generating strong dielectric polarization under an electric field, enabling small-volume components to achieve relatively high capacitance. The miniaturization of multilayer ceramic capacitors depends on the high dielectric response of barium titanate-based ceramics, as well as on the control of powder particle size, grain size, grain boundaries, sintering density, internal electrodes, and defects. Class II ceramic capacitors are usually based on barium titanate-based materials. They have relatively high dielectric constants, but their capacitance is affected by temperature, DC bias, and time.

 

1. What Problems Does Barium Titanate Solve in Multilayer Ceramic Capacitors?

 

The chemical formula of barium titanate is BaTiO. Its crystal structure can be understood in terms of three parts: the barium site, the titanium site, and the oxygen site.

 

Structural position

Corresponding component

Role in dielectric performance

Barium site

Barium ion

Supports the perovskite lattice and affects lattice size and phase stability

Titanium site

Titanium ion

Located inside the oxygen octahedron and serves as a key center for polarization response

Oxygen site

Oxygen ion

Forms the oxygen octahedral framework; oxygen vacancies affect leakage, loss, and reliability

 

Barium titanate is suitable as a ceramic capacitor material mainly because it addresses three needs:

 

Capacitor requirement

Function provided by barium titanate

Achieving relatively high capacitance in a small volume

High dielectric constant increases capacitance per unit volume

Forming ceramic dielectric layers

Suitable for powder preparation, tape casting, stacking, and sintering

Tunable performance through modification

Doping, solid solution formation, and sintering control can improve temperature stability, dielectric loss, and reliability

 

A multilayer ceramic capacitor is not a single ceramic sheet. It is formed by alternately stacking ceramic dielectric layers and metal internal electrodes. In essence, it is a parallel combination of many ceramic parallel-plate capacitor units. Barium titanate-based ceramics, with their relatively high dielectric constant, are well suited to this type of high-capacitance, miniaturized design.

 

2. Why Does Barium Titanate Have a High Dielectric Response?

 

To store charge, a capacitor requires its dielectric material to polarize under an electric field. In the perovskite structure of barium titanate, the titanium ion is located inside an oxygen octahedron. In the ferroelectric phase, the titanium ion can deviate from the centrosymmetric position, so the centers of positive and negative charge no longer fully coincide, producing spontaneous polarization. Below the Curie temperature, barium titanate exhibits spontaneous polarization and domain structures, which are important sources of its high dielectric response.

 

Structural behavior

Dielectric result

Titanium ion deviates from the center of the oxygen octahedron

Generates local electric dipoles

Electric dipoles respond to the electric field

Increases dielectric constant

Ferroelectric domain walls move reversibly

Enhances small-signal dielectric response

Temperature approaches a phase-transition region

Dielectric constant changes significantly

Grains, grain boundaries, and defects change

Dielectric constant, loss, and reliability change together

 

The high dielectric performance of barium titanate is not determined by chemical formula alone. Even for BaTiO, differences in powder particle size, Ba/Ti ratio, grain size, grain-boundary state, and sintering atmosphere can lead to significantly different final dielectric properties. Grain size, phase transitions, domain walls, and grain boundaries in barium titanate all affect its dielectric and piezoelectric properties. In practical multilayer ceramic capacitors, barium titanate is usually modified through solid solution formation, rare-earth doping, grain-boundary control, and sintering optimization. The dielectric peak may be broadened or shifted, so the temperature characteristics of a device cannot be judged solely from the phase-transition temperature of pure BaTiO.

 

3. How Do Multilayer Ceramic Capacitors Achieve Miniaturization?

 

Capacitance is mainly affected by three factors: the dielectric constant of the dielectric material, the effective electrode area, and the thickness of the dielectric layer. Multilayer ceramic capacitors achieve relatively high capacitance in a small volume by increasing the dielectric constant, reducing the thickness of the ceramic dielectric layer, and increasing the number of stacked layers.

 

Miniaturization pathway

Contribution to capacitance

Requirements for materials and processing

Use high-permittivity barium titanate-based ceramics

Improves charge-storage capability per unit volume

High dielectric constant, low loss, high insulation resistance

Reduce dielectric layer thickness

Increases capacitance density

Fine powders, uniform films, few defects

Increase the number of stacked layers

Increases the effective parallel electrode area

Stable tape casting, stacking, pressing, and co-firing

Use continuous internal electrodes

Increases effective electrode area

Electrode paste, sintering atmosphere, and interface matching

Improve ceramic density

Reduces leakage and breakdown risk

Control of pores, cracks, and abnormal grains

 

Miniaturization is not simply a matter of making the ceramic layers thinner. The thinner the dielectric layer, the more likely pores, coarse grains, secondary phases, cracks, and local thickness nonuniformity are to become weak points for breakdown. Therefore, high-capacitance multilayer ceramic capacitors must satisfy both high dielectric performance and high reliability.

 

4. Why Do Barium Titanate-Based Materials Usually Require Modification?

 

Pure barium titanate has a relatively high dielectric response, but its dielectric properties are sensitive to temperature and phase transitions. In electronic components, capacitors need to maintain acceptable capacitance and insulation performance over a specified temperature range, under DC voltage, and during long-term storage. Therefore, barium titanate-based materials usually require modification.

 

Modification objective

Problem addressed

Common direction

Improve temperature stability

Avoid large capacitance fluctuations with temperature

Solid-solution or composite regulation using strontium titanate, calcium zirconate, barium zirconate, and related materials

Reduce dielectric loss

Reduce heating and energy loss

Combined acceptor/donor doping, grain-boundary barrier control, and control of oxygen-vacancy migration

Increase insulation resistance

Reduce leakage

Rare-earth, manganese-based, magnesium-based, and related additives combined with reoxidation treatment to regulate grain-boundary resistance, electronic defects, and oxygen-vacancy migration

Improve breakdown strength

Withstand higher electric fields

Fine grains, high density, reduced pores and cracks

Control grain growth

Avoid abnormal grains that create local weak points

Doping, sintering aids, and control of the sintering schedule

Improve batch stability

Reduce formulation and process fluctuations

Control of powder particle size, Ba/Ti ratio, and mixing uniformity

 

5. Capacitance Changes in Barium Titanate-Based Capacitors: Temperature, DC Bias, and Aging

 

Barium titanate-based Class II ceramic capacitors have high dielectric constants, but their capacitance is not fixed. When using or evaluating these capacitors, three types of changes require particular attention: temperature dependence, DC bias dependence, and aging.

 

5.1 Temperature Change

 

Barium titanate is a ferroelectric material, and its crystal structure and domain response vary with temperature. When temperature changes, the dielectric constant changes accordingly, and the capacitance also changes.

 

Temperature-related factor

Capacitance behavior

Crystal phase transition

Capacitance changes significantly in certain temperature ranges

Change in domain-structure response

Dielectric constant varies with increasing or decreasing temperature

Change in defect and grain-boundary response

Dielectric loss and insulation performance may change

Different modified formulations

Different temperature-stability classes are obtained

 

Class I ceramic materials have better temperature stability and lower dielectric constants, so their capacitance is usually lower under the same size and structure. Class II ceramic materials are often based on barium titanate-based compositions and can provide relatively high capacitance in a small volume, but they are affected by temperature.

 

5.2 DC Bias

 

Under a DC voltage, the capacitance of barium titanate-based Class II ceramic capacitors usually decreases. This is because the DC electric field causes some ferroelectric domains and polarization states to become oriented. As a result, the response space available for domain-wall motion and nonlinear polarization under a small-signal electric field is reduced, lowering the effective dielectric constant.

 

DC bias effect

Device behavior

Polarization tends to become oriented

Small-signal dielectric response decreases

Domain-wall motion is restricted

Effective dielectric constant decreases

Electric field increases inside thin dielectric layers

Breakdown and reliability stress increase

High-capacitance, small-size devices are more sensitive

Effective capacitance under operating voltage may be lower than the nominal value

 

5.3 Aging Over Time

 

After sintering and cooling, after de-aging heat treatment, or after reflow soldering/high-temperature treatment sufficient to exceed the Curie temperature, Class II ferroelectric ceramic capacitors begin from a relatively high initial capacitance state and then gradually lose capacitance during storage. This phenomenon is called aging. It is related to the gradual stabilization of ferroelectric domains, interactions between defects and domain walls, and the tendency of the crystal structure to stabilize over time.

 

Aging is usually expressed as an “aging rate,” meaning the approximate percentage decrease in capacitance for each tenfold increase in time under specified conditions. For example, if capacitance decreases by a similar percentage from 1 hour to 10 hours and from 10 hours to 100 hours, the aging rate can be used to describe this trend. In practical evaluation, the test starting point, test duration, temperature conditions, and capacitance retention should be specified.

 

Source of aging

Capacitance behavior

Ferroelectric domains gradually stabilize

Responsive polarization decreases

Defects interact with domain walls

Domain-wall motion is restricted

Lattice state adjusts over time

Capacitance slowly decreases

Cooling after heating above the Curie temperature

Aging state can be restarted

 

6. How Do Powders, Grains, and Grain Boundaries Affect Dielectric Performance and Reliability?

 

The dielectric layers in multilayer ceramic capacitors are very thin. In barium titanate-based ceramics, pores, abnormal grains, local compositional segregation, and grain-boundary defects can all become weak points for leakage or breakdown. Powder particle size and particle-size distribution affect tape casting, sintering densification, and final grain size. Grain size and grain-boundary structure further affect dielectric constant, dielectric loss, insulation resistance, breakdown strength, and capacitance uniformity. Grain refinement usually helps improve the uniformity of thin dielectric layers and breakdown strength, but excessive grain refinement may weaken the contribution of ferroelectric domains and domain walls to the dielectric constant. Therefore, grain-size control should balance dielectric constant, dielectric loss, breakdown strength, and DC bias characteristics.

 

Thus, even for the same barium titanate-based formulation, differences in powder dispersibility, sintered density, grain uniformity, and grain-boundary insulation state can lead to significant differences in final capacitance, dielectric loss, withstand voltage, and long-term reliability.

 

Microstructural factor

Main direction of influence

Priority observations in experiments

Powder particle size

Affects tape-casting uniformity, sintering activity, and final grain size

Particle-size distribution, agglomeration state, slurry dispersibility

Powder purity

Affects secondary phases, leakage, and dielectric loss

Metallic impurities, residual carbonates, phase purity

Green-body density

Affects sintering shrinkage, pores, and layer-thickness uniformity

Green density, pore distribution, interlayer defects

Grain size

Affects dielectric constant, domain structure, DC bias characteristics, and breakdown strength

Average grain size, grain-size distribution

Abnormal grains

May form local electric-field concentration and weak breakdown points

Coarse grains, local nonuniform regions

Grain-boundary structure

Affects insulation, leakage, aging, and reliability

Grain-boundary phases, grain-boundary segregation, grain-boundary resistance

Pores and cracks

Reduce breakdown strength and mechanical reliability

Porosity, cracks, delamination defects

 

7. How Do the Sintering Process and Internal Electrodes Affect Device Reliability?

 

Multilayer ceramic capacitors are formed by alternately stacking ceramic dielectric layers and metal internal electrodes. The sintering process must not only fully densify the barium titanate-based ceramic, but also maintain internal electrode continuity, stable interlayer bonding, and reduced defects such as pores, cracks, residual carbon, and abnormal grains.

 

When sintering and internal-electrode matching are poor, the device may still show increased leakage, reduced breakdown strength, greater capacitance dispersion, or insufficient long-term reliability, even if the dielectric formulation itself has a high dielectric constant.

 

Process step

Main direction of influence

Tape casting

Affects dielectric layer thickness, film uniformity, and local defect distribution

Stacking and lamination

Related to interlayer bonding, thickness consistency, and structural integrity

Binder burnout

Removes organic matter and reduces the risk of residual carbon, pores, and cracking

Co-firing

Promotes ceramic densification, grain growth, and formation of continuous internal electrodes

Atmosphere control

Affects defect states in barium titanate, electrode oxidation/reduction, and dielectric insulation performance

Termination processing

Affects external connection, soldering reliability, and terminal mechanical strength

 

Precious-metal internal electrode systems are usually represented by palladium or silver-palladium alloys. They have a relatively broad processing window, but the metal cost is high. Increasing the silver content can reduce electrode cost and alloy melting point, but pure silver is generally not suitable for co-firing as an internal electrode with ordinary high-temperature barium titanate ceramics. It is more often used in low-temperature sintering systems, external electrodes, or specific silver-based electrode studies. Nickel is an important base-metal internal electrode material in modern multilayer ceramic capacitors and helps reduce electrode cost, but it must be co-fired under a low oxygen partial pressure or reducing atmosphere to avoid nickel oxidation. Therefore, barium titanate-based dielectrics need reduction resistance and must maintain insulation resistance and long-term reliability through grain-boundary and defect control.

 

Failure behavior

Common direction of cause

Increased leakage

Increased oxygen vacancies, insufficient grain-boundary insulation, secondary-phase formation, or excessive reduction

Reduced breakdown strength

Locally thin layers, pores, abnormal grains, cracks, or electrode burrs

Greater capacitance dispersion

Nonuniform layer thickness, poor powder dispersion, inconsistent sintering shrinkage, or uneven electrode coverage

Unstable temperature characteristics

Insufficient phase-transition control, formulation deviation, or nonuniform grain-size distribution

Mechanical cracking

Ceramic brittleness, thermal stress, bending stress, soldering stress, or insufficient interlayer bonding

Insufficient long-term reliability

Grain-boundary degradation, defect migration, humidity/thermal effects, or electrode-interface reactions

 

Failure in barium titanate-based multilayer ceramic capacitors may originate from external structural defects, such as delamination, cracks, pores, and local weak points. It may also originate from intrinsic material issues, such as insufficient grain-boundary insulation, second-phase formation, excessive oxygen vacancies, and increased electronic defects. When evaluating these devices, the dielectric formulation, powder state, sintering schedule, atmosphere control, and internal-electrode matching should be considered together.

 

8. Which Indicators Should Be Checked First When Deciding Whether a Barium Titanate-Based Ceramic Formulation Is Worth Further Optimization?

 

The evaluation of barium titanate-based ceramics cannot rely only on dielectric constant. A high dielectric constant helps increase capacitance, but if it is accompanied by increased dielectric loss, decreased insulation resistance, insufficient breakdown strength, excessive capacitance variation with temperature, or obvious aging, the material’s application value in multilayer ceramic capacitors will be limited.

 

Experimental objective

Priority indicators

Key points for evaluation

Increase capacitance

Dielectric constant, layer thickness, effective electrode area

Whether the increase in dielectric constant is accompanied by increased loss

Improve temperature stability

Capacitance–temperature curve, dielectric loss–temperature curve

Whether the target temperature range is satisfied

Reduce dielectric loss

Dielectric loss, frequency response, leakage current

Whether defect conduction or grain-boundary problems exist

Improve withstand voltage

Breakdown strength, porosity, grain size

Whether local electric-field concentration exists

Improve long-term stability

Aging rate, insulation resistance, damp-heat testing

Whether capacitance and insulation performance deteriorate over time

Improve process reproducibility

Powder particle size, sintered density, batch data

Whether the formulation has a stable sintering window

 

9. What Problems Do Different Types of Chemicals Solve in Barium Titanate-Based Capacitor Materials?

 

Chemicals related to barium titanate-based multilayer ceramic capacitors should be understood according to their functions in the dielectric matrix, temperature characteristics, grain-boundary defects, sintering and forming, and electrode co-firing. Different materials solve different problems, and their amount, particle size, purity, and method of addition all affect the final dielectric performance and reliability.

 

Material category

Representative material or component

Main function

Main dielectric material

Barium titanate

Provides high dielectric response and serves as the core matrix of Class II high-permittivity ceramic dielectrics

Temperature-characteristic modifier

Strontium titanate, barium zirconate, calcium zirconate

Regulates phase-transition behavior and dielectric peak position, improving capacitance variation with temperature

Rare-earth grain-boundary and defect modifier

Lanthanum oxide, yttrium oxide, samarium oxide, dysprosium oxide

Regulates grain growth, grain-boundary barriers, insulation resistance, and long-term reliability; the specific effect depends on ionic radius, site occupation, dopant level, Ba/Ti ratio, and sintering atmosphere

Defect and loss modifier

Manganese oxide, magnesium oxide, cobalt oxide

Regulates defect states, leakage current, dielectric loss, and grain-growth behavior

Sintering and grain-boundary phase modifier

Silicon dioxide, boron oxide, glass-powder systems

Promotes densification and regulates grain-boundary phases, sintering temperature, and the sintering window

Internal electrode material

Nickel, silver-palladium systems

Forms internal electrodes and affects co-firing atmosphere, interface stability, cost, and reliability

Forming auxiliary material

Polyvinyl butyral, plasticizers, dispersants

Improves tape casting, forming, stacking, binder burnout, and green-body strength

 

The key relationships in material selection can be summarized as follows:

 

Selection target

Key related issues

Barium titanate powder

Dielectric foundation, powder activity, sintering behavior, and grain control

Solid-solution modifier

Temperature characteristics, dielectric peak position, and capacitance–temperature stability

Grain-boundary and defect modifier

Leakage current, dielectric loss, insulation resistance, aging, and breakdown strength

Sintering aid

Density, sintering temperature, grain-boundary phase, and grain growth

Internal electrode material

Co-firing atmosphere, interface matching, electrical conductivity, cost, and long-term reliability

Forming auxiliary material

Slurry stability, green-body strength, layer-thickness uniformity, and binder-burnout quality

 

Summary: Barium titanate determines the dielectric foundation; solid-solution modifiers regulate temperature characteristics; grain-boundary and defect modifiers control loss and reliability; sintering and forming materials affect process stability; and internal electrode materials influence co-firing conditions and device lifetime.

 

10. Selection Guide for Barium Titanate-Based Ceramic Capacitor Materials (Tables 1–4)

 

Research or experimental objective

Recommended table to review first

Why start with this table

Tables to review together

Guidance note

Establish a basic formulation for barium titanate-based ceramic capacitor dielectrics

Table 1

Table 1 focuses on barium titanate, strontium titanate, barium zirconate, and calcium zirconate, allowing the main dielectric matrix and temperature-characteristic modification direction to be determined first

Tables 2 and 3

First determine the barium titanate matrix and solid-solution modification direction, then combine synthetic raw materials, grain-boundary modifiers, and defect-control materials to refine the formulation

Prepare barium titanate or solid-solution modified powders from raw-material routes

Table 2

Table 2 includes barium carbonate, titanium dioxide, strontium carbonate, calcium carbonate, and zirconium dioxide, which can be used for solid-state reaction and powder-synthesis route design

Tables 1 and 4

Suitable for experiments focused on phase purity, Ba/Ti ratio, particle size, reaction activity, and sintering behavior

Improve capacitance variation with temperature

Table 1

Strontium titanate, barium zirconate, and calcium zirconate in Table 1 are directly related to the barium titanate matrix and can be used to regulate phase-transition behavior and dielectric temperature characteristics

Table 3

If temperature stability is still affected by grain boundaries, defects, or dielectric loss, Table 3 can be reviewed together to evaluate rare-earth oxides and transition-metal oxides

Study grain size, sintering density, and phase purity of barium titanate-based ceramics

Table 2

The raw materials in Table 2 determine powder reactivity, compositional uniformity, and initial particle size, which are upstream factors affecting grain growth and sintering behavior

Tables 3 and 4

Start with powder synthesis and raw-material particle size, then combine doping control and sintering aids to evaluate densification effects

Reduce dielectric loss, leakage, and insulation-failure risk

Table 3

Table 3 focuses on rare-earth oxides, niobium oxide, manganese dioxide, magnesium oxide, and cobalt oxide, which are directly related to grain-boundary, oxygen-vacancy, and defect control

Table 4

When loss or leakage is related to sintering atmosphere, grain-boundary phases, or electrode co-firing, Table 4 should be reviewed together to check sintering and electrode conditions

Improve breakdown strength and long-term reliability

Table 3

Breakdown strength is closely related to grain-boundary insulation, pores, abnormal grains, and defect states; the materials in Table 3 can be used for defect and grain-boundary regulation

Tables 2 and 4

Powder particle size, sintering density, pores, grain-boundary phases, and electrode interfaces should be checked together

Design low-temperature sintering or grain-boundary phase regulation experiments

Table 4

Table 4 includes diboron trioxide, silicon dioxide, and forming binders, which can be used for research on sintering aids, glass phases, and tape-casting/forming processes

Table 3

If low-temperature sintering causes increased dielectric loss or decreased insulation performance, Table 3 should be used together to adjust defect and grain-boundary states

Establish experiments related to ceramic tape casting, stacking, and binder burnout

Table 4

Polyvinyl butyral in Table 4 corresponds to ceramic forming and green-film strength control, making it an important material for multilayer ceramic capacitor process research

Table 2

Forming quality is also affected by powder particle size, dispersibility, and solid content; Table 2 can be used together to check powder source and particle-size basis

Compare the effects of precious-metal and base-metal electrodes on device structure

Table 4

Table 4 includes silver, nickel, and palladium, which can be used for research on electrode materials, co-firing atmosphere, and interface stability

Table 3

Nickel electrode systems require attention to dielectric insulation and oxygen-vacancy changes under reducing atmosphere; Table 3 can be used together for defect control

Analyze causes of large capacitance dispersion, high dielectric loss, or batch instability

Table 2

Batch differences are often related to raw-material purity, particle size, mixing uniformity, and completeness of solid-state reaction; Table 2 can be used first for upstream troubleshooting

Tables 3 and 4

First check raw materials and powder processing, then examine dopant distribution, sintering schedule, binder burnout, and electrode interfaces

Establish a complete material-screening route for multilayer ceramic capacitors

Table 1

Table 1 first determines the main dielectric material and the direction of temperature-characteristic modification, making it the starting point for formulation design

Tables 2, 3, and 4

An experimental route can be built in the sequence of “main dielectric material—synthetic raw materials—grain-boundary and defect control—sintering, forming, and electrodes”

Conduct control experiments on barium titanate-based ceramic capacitor materials

Table 1

Table 1 includes barium titanate and the main temperature-characteristic modifiers, making it convenient to establish controls among the matrix, solid-solution, and modified systems

Tables 2 and 3

Control experiments should record dielectric constant, dielectric loss, temperature curve, breakdown strength, insulation resistance, and sintered density at the same time

 

Table 1|Main Dielectric Materials and Temperature-Characteristic Modifiers

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or purity

Product features and applications

Main high-permittivity perovskite material

12047-27-7

B106131

Barium titanate

PrimorTrace™, ≥99.99% metals basis

Core dielectric material for barium titanate-based ceramic capacitors; can be used in studies of high-permittivity ceramics, dielectric temperature characteristics, grain-size effects, and sintering processes

Perovskite material for temperature-characteristic regulation

12060-59-2

S118843

Strontium titanate

≥99.5% metals basis, ≤5 μm

Can form a solid-solution regulation system with barium titanate; used to reduce phase-transition sensitivity, improve dielectric temperature stability, and study barium strontium titanate ceramics

Material for temperature-characteristic and phase-transition regulation

12009-21-1

B476606

Barium zirconate

≥99% metals basis

Can be used for solid-solution modification and phase-transition regulation of barium titanate-based ceramics; suitable for studying dielectric peak broadening, temperature stability, and high-insulation ceramic formulations

Material for temperature-characteristic and grain-growth control

12013-47-7

C477831

Calcium zirconate

≥99.7% metals basis

Can be used for zirconium–calcium component regulation in barium titanate-based ceramics; commonly used in studies of temperature-characteristic improvement, grain-growth control, and dielectric reliability

 

Table 2|Raw Materials for Barium Titanate-Based Powder Synthesis and Solid-Solution Components

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or purity

Product features and applications

Calcium source and raw material for calcium zirconate synthesis

471-34-1

C432744

Calcium carbonate

Anhydrous grade, ACS, ≥99%

Can serve as a calcium source for calcium zirconate, calcium-modified barium titanate, and solid-state reaction systems; suitable for studying the influence of calcium components on grain growth and dielectric temperature characteristics

Titanium source for titanate synthesis

13463-67-7

N1519826

Nano Titanium oxide

Electronic grade, ≥99.8% metals basis, 300–700 nm

Can serve as a titanium source for the synthesis of barium titanate and strontium titanate; the nanoscale particle size is beneficial for studies of solid-state reaction activity, powder uniformity, and sintering behavior

Barium source for barium titanate synthesis

513-77-9

B1519978

Barium carbonate

Electronic grade, ≥99.8% metals basis

Common barium source for solid-state synthesis of barium titanate powders; can be used for Ba/Ti ratio control, phase-purity optimization, and raw-material formulation studies for high-permittivity ceramics

Strontium source for strontium titanate synthesis

1633-05-2

S102043

Strontium Carbonate

Electronic grade, ≥99.5%, 0–1 μm

Can serve as a strontium source for preparing strontium titanate and barium strontium titanate systems; suitable for studying the influence of strontium components on dielectric temperature stability and phase-transition behavior

Raw material for zirconates and zirconium modification

1314-23-4

Z305381

Zirconium dioxide

≥99%

Can serve as a zirconium source for barium zirconate, calcium zirconate, and zirconium-modified barium titanate systems; suitable for studying the influence of zirconium components on phase transitions, insulation performance, and breakdown strength

 

Table 3|Materials for Grain-Boundary, Defect, Insulation, and Dielectric-Loss Control

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or purity

Product features and applications

Rare-earth grain-boundary modifier

12060-58-1

S431576

Samarium(III) oxide dispersion

Nanoparticles, <100 nm particle size (BET)

Can be used for rare-earth modification of barium titanate-based ceramics; suitable for studying grain-boundary insulation, grain-growth control, and dielectric reliability

Donor-type modifier

1313-96-8

N108410

Niobium pentaoxide

Electronic grade, ≥99.98% metals basis

Can be used in niobium-doped barium titanate systems involving niobium pentoxide to study donor doping, charge compensation, grain growth, and dielectric response; insulation changes should be evaluated together with Ba/Ti ratio, co-doping, and sintering atmosphere

Acceptor-type defect-control material

1313-13-9

M101137

Manganese dioxide

PureSpectra™, spectroscopic grade

Can be used to regulate oxygen vacancies and reduce leakage and dielectric loss in barium titanate-based ceramics; suitable for studies of high insulation resistance and aging stability

Rare-earth grain-boundary and insulation modifier

1312-81-8

L103871

Lanthanum oxide

PureSpectra™, spectroscopic grade

Can be used for rare-earth doping and grain-boundary control in barium titanate-based ceramics; suitable for studying insulation resistance, dielectric loss, and temperature stability

Rare-earth grain-boundary and sintering modifier

1314-36-9

Y103888

Yttrium oxide

PrimorTrace™, ≥99.999% metals basis

Can be used to improve grain-boundary states, sintering behavior, and dielectric reliability in barium titanate-based ceramics; suitable for high-purity electronic ceramic formulation studies

Transition-metal defect-control material

1307-96-6

C105672

Cobalt oxide

PrimorTrace™, ≥99.99% metals basis

Can be used to regulate defect states and conductive behavior in barium titanate-based ceramics; suitable for studying leakage, dielectric loss, and the influence of sintering atmosphere

Grain-growth and insulation-control material

1309-48-4

M103941

Magnesium oxide

PrimorTrace™, ≥99.99% metals basis

Can be used for grain-growth control and insulation regulation in barium titanate-based ceramics; suitable for studying breakdown strength, grain-boundary structure, and dielectric loss

Rare-earth grain-boundary and reliability modifier

1308-87-8

D105275

Dysprosium oxide

PrimorTrace™, ≥99.99% metals basis

Can be used for rare-earth modification of barium titanate-based ceramics; suitable for studying grain-boundary insulation, temperature stability, aging behavior, and high-reliability capacitor dielectrics

 

Table 4|Glass-Phase Regulation, Ceramic Forming Auxiliaries, and Electrode Reference Materials

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or purity

Product features and applications

Ceramic forming binder

63148-65-2

M1508536

Mowital® SB 60 HH Polyvinyl butyral (PVB)

Solids content ≥97.5%; viscosity 120.0–280.0 mPa·s

Can be used in ceramic tape casting, stacking, and forming processes to improve green-film strength, flexibility, and interlayer bonding stability

Low-temperature sintering and glass-phase component

1303-86-2

D431708

di-Boron trioxide

Ultrapure grade, ≥99.9995% metals basis

Can serve as a glass-phase and low-temperature sintering component to improve densification, lower sintering temperature, and regulate grain-boundary phases

Low-temperature sintering and grain-boundary phase component

7631-86-9

S116482

Silicon dioxide

AR, ≥99%

Can be used in glass-phase, grain-boundary phase, and sintering-aid systems; suitable for studying densification, grain control, and changes in dielectric loss

Silver-based electrode powder material

7440-22-4

S776852

Silver

D50: 0.30–0.50 μm; specific surface area: 0.8–1.5 m²/g

Fine silver powder; can be used for control studies of silver-based electrode pastes, low-temperature sintered electrodes, and silver-palladium electrode systems; suitable for evaluating metal powder dispersibility, electrode continuity, electrical conductivity, and ceramic interface matching. When used with barium titanate-based dielectrics, sintering temperature and silver-migration risk should be considered

Nickel-based internal electrode powder material

7440-02-0

N434833

Nickel

PrimorTrace™, ≥99.99% metals basis, powder, <150 μm

Can serve as a research raw material for nickel internal electrode systems and non-precious-metal electrode systems; used to investigate reducing-atmosphere co-firing, reduction-resistant barium titanate dielectrics, nickel–ceramic interface reactions, and electrode stability. Because the particle-size range is relatively broad, particle-size distribution, dispersibility, and sintering-shrinkage matching should be further evaluated if used for thin-dielectric-layer internal electrode pastes

Precious-metal electrode powder material

7440-05-3

P106012

Palladium

≥99.9% metals basis, ≤1 μm

Submicron palladium powder; can be used in studies of palladium electrodes and silver-palladium alloy electrode systems; suitable for evaluating sintering resistance, electrode continuity, interface stability, and co-firing compatibility with barium titanate-based ceramics. It can also serve as a precious-metal reference for nickel electrode systems

 

Note: The above are representative Aladdin products. More product specifications can be searched on the Aladdin website by product name, CAS number, or catalog number.

 

References

 

[1] Acosta M., Novak N., Rojas V., Patel S., Vaish R., Koruza J., Rossetti G. A., Rödel J. BaTiO-based piezoelectrics: Fundamentals, current status, and perspectives. Applied Physics Reviews, 2017, 4: 041305.

 

[2] Buscaglia V., Randall C. A. Size and scaling effects in barium titanate. An overview. Journal of the European Ceramic Society, 2020, 40: 3744–3758.

 

[3] Kahn M. Multilayer Ceramic Capacitors: Materials and Manufacture. Kyocera AVX.

 

[4] Rawal B. S., Chan N. H. Conduction and Failure Mechanisms in Barium Titanate Based Ceramics Under Highly Accelerated Conditions. Kyocera AVX.

 

[5] TDK Product Center. What is the difference between a Class I capacitor and a Class II capacitor?

 

[6] TDK Product Center. Does the capacitance of an MLCC change with temperature?

 

[7] TDK Product Center. What is MLCC “aging”?

 

For more related articles, see below.

 

Perovskite PV/PeLED Precursor Guide: Selecting Metal Halide Salts, Key Conditions, and Reproducible Performance (including Product Tables 1–4 and a Selection Navigation Guide)

 

Perovskite Quantum Dots (PQDs)

 

Structure, Synthesis, and Applications of Barium Titanate – A Closer Look at the Core Dielectric Material in MLCCs

 

Ceramic Materials Guide: Basic Definitions, Classification Framework, and Research-Task-Oriented Selection (with Product Navigation and Tables 1–4)

Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

Products are supplied for research and development use only. Not for use in humans, animals, diagnosis, or therapy.

Cite this article

Aladdin Scientific. "From Barium Titanate Dielectrics to Multilayer Ceramic Capacitors: Dielectric Properties and Experimental Evaluation of Barium Titanate-Based Ceramics" Aladdin Knowledge Base, updated May 13, 2026. https://www.aladdinsci.com/us_en/faqs/from-barium-titanate-dielectrics-to-multilayer-ceramic-capacitors-en.html
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