Processing ZnS based

electroluminescent precursor powder

mixtures with TNT

Greg Kennedy and S. Itoh

5/9/2008

Outline

• Introduction• Electroluminescence• Summary of patent application

– US patent application pub# (20070080327)– European Union Patent (WO2007043676)

• Investigation of the process• ZnS explosive processing literature• Preliminary experiments• Conclusions and Future Work

Display Technology

LCD

Plasma

EL-11 inch

3mm $2500

Electroluminescence

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Examples of different wavelengths obtained by doping

Electroluminescent material search

• The research has been financed by companies in a very competitive and fast growing field

• Most publicly available information is found in patents and patent applications

• Look at one recent patent and some older published works

Patent Application InformationUS patent application pub# (20070080327)

• Starting Materials– Primarily ZnS, (Zinc Sulfide) – Mn and Ir (activators, emission centers)– Ba and Mg

• Explosive Chamber discussion• Final heat treatment• Gallium Arsenide compound semiconductor

• Standard manufacturing of EL element

Explosive Chamber (patent info)

• 0.01mmHg vacuum (~1Pa)

• 32g TNT selected for 50MPa in one liter chamber

• TNT is exploded by heater (4) upon heating to 450˚C

• ~109g Sample mixture(8) is placed under TNT

• Produced “calcined cake”

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Concerns due to limited information in the Patent

• Is the explosive separated from the sample?• Does the TNT detonate by heating?• Does the TNT melt, boil before detonation?

– How does the vacuum change the detonation process?

– What is heating rate?• Controls temperature of the powder

• And detonation of TNT

• Maybe electric detonator is ok, but heating of powder might be necessary for desired final performance

Final Material Processing

• Explosive loading

• “Calcined cake” is allowed to cool

• Washed with deionized water, Dried

• Pulverizer/Separator powder (5-20µm)

• 8 hours Calcining in nitrogen atmosphere at 700˚C in a silica tube

• Washed with glacial acetic acid

– Remove excessive compounds, flux and impurities

• Rinsed with deionized water

Sample B Sample C• Explosive Loading

• “Calcined cake” is allowed to cool

• Washed with deionized water, Dried

• Pulverizer/Separator powder (5-20µm)

• 0.005g GaAs mixed with 15g of powder in mechanical stirrer

• 8 hours Calcining in nitrogen atmosphere at 700˚C in a silica tube

• Washed with glacial acetic acid

– Remove excessive compounds, flux and impurities

• Rinsed with deionized water

(patent info)

Increased Luminosity

• Increased from 400 to 4000 cd/m^2

• “The reason for the excellent properties … is due to instantaneous high temperature, light emission and/or shock wave produced by the explosion. However, particulars of the mechanism for the development of such favorable properties are still unknown.”

*Patent application US2007/0080327A1

Zinc Sulfide

• Sphalerite

• Cubic

• Band Gap 3.54eV

• Wurtzite

• Hexagonal

• Band Gap 3.67eV

Phase Change --->1019˚C

High pressure phase change to a different Rock Salt type structure 15GPa

Mashimo (1999)

Photoluminescence of Zinc Sulfide after Dynamic Compression

Pure ZnS does not exhibit photoluminescence, but after dynamic compaction bright photoluminescence occurs due to microdefects created by shock loading

Phase change from sphalerite to wurtzite

Fluorescence microscopic observation showed blue particles and green particles

Blue particle concentration can be increased by adding sulphur

The increase in Zn vacancies from the increase in sulphur causes an increase in photoluminescence intensity

Photoluminscence is reduced after roasting shock loaded sample

*Batsonov, Fizika Goreniya I Vzryva, Vol. 3, No. 3, pp441-448 1967

Shock Assisted Doping

• Efficient process– Vacancies and interstitials

• Heterogeneous distribution of defects• Heterovalent doping is possible

– Eu2+ in NaCl type systems (example)– Create charge defects

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Lapshin and Kurnikova, ZPS, Vol 28. No1, 95-100, Jan. 1978

Explosive Doping

• Emission bands are shifted to longer wavelengths compared to thermally processed materials– Same occurs in thermally produced material after shock loading

• The chemical form of the can change the wavelength – MnS emission band at 589µm– Mn(NO3)2 demission at 570µm

• Inhomogeneous phase transformation of cubic and hexagonal phase generates large number of defects

• Emission bands are wider than thermally produced ZnS:Cu• Traps are formed, causing long time phosphorescence

*Lapshin, et. al, ZPS, vol 14, no 6, 1020-1026, June 1971

Explosive Doping Literature

• Pre-shock starting material before firing

• 8GPa Detonating pressure from tetryl

• Fired for 2hrs at 1250oC

• The pre-shocked sample had 40% increased intensity with slight shift to shorter wavelengths under excitation by 254µm source

*Horiguchi - Pre-shock Treatment for Preparation of Zn2SiO4(Mn) Phosphor having High Luminescence Intensity, Naturwissenschaften (1966)

Zn2SiO4(Mn)

Hypothesis of patent mechanism• The TNT is heated to 450oC

– Melting point 80.9oC– Boiling Point 295oC

• Location for Temperature not described

• TNT– Melts, then boils– The boiling tnt mixes with EL

powder– Vapor evolves and is ignited by

the hot nichrome heater wire– Localized heating causes

deflagration in the TNT

T1

T2 T3

Experimental Procedure• Heat the TNT to 450 and test for deflagration or detonation

• Examine mixing of liquid TNT and precursor powder

• Test the powder for exothermic reaction upon heating to 450 (thermal analyzer)

• Duplicate the patent experiment– Initiation of deflagration by heated wire

– Heating from the base by heater external to the powder container

Heating the TNT

Video of TNT burning

Frame 1

Frame 2

Mixing of TNT and ZnS

• Examine the possibility of mixing of the TNT and precursor powders– Nichrome wire heater in plaster– 10grams of ZnS– 20grams TNT– Glass container

• video

Conclusions

• TNT deflagrates upon heating– There is no explosion as described in the patent

• Heating the TNT and the powder can lead to extensive mixing– This would allow good heat transfer to the

precursor powder and promote localized doping

Future Work

• Using the observations from this work – Proceed to examine the powder mixture

described in the Chatani Patent

Starting Materials (patent info)• Sample A -conventional method• Sample B

– ZnS 100g– MnSO4 0.27g– ZnO 0.5g– BaF2 3g– MgCl2 3g– IrCl3 0.012g– NaCl 2g

• Sample C– 15g of Sample B after explosive processing and

pulverizing – 0.005g Gallium Arsenide (1-3µm) compound

Semiconductor• Mechanical stirrer in plastic bottle (20 minutes)

Comparative Sample A

• 7g ZnSO4 0.5g CuCl 0.5g CuSO4

• 800oC for 40 minutes

• From JP-A No. 2005-126465

Luminance

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Example 1 and 2 ,Measurement is at 280V at 8 KHz

Example 3 voltage was increased to maintain constant luminance , 315 V after 24hrs, and 330 after 100 hours, stable 120 hours to 1000 hours

EL Element

• Silk screen of sample A, B, C onto BaTiO3

– Greater than 80% of particles 12 to 18µm

• Barium titanate is deposited on the emitting layer

• Electrode is deposited on the BaTiO3

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