Atmospheric pressure plasma

sources suitable for

modification of wood surfaces

Gheorghe Dinescu National Institute for Laser, Plasma and Radiation

Physics, Bucharest, Romania

(dinescug@infim.ro)

(Acknowledgments: Dana Ionita, Max Teodorescu, Rosini Ionita, Cristian

Stancu, Claudia Stancu)

NILPRP

PHYSICS RESEARCH - ROMANIACAMPUS MAGURELE, BUCHAREST-

NATIONAL RESEARCH INSTITUTES

• National Institute for Physics and Nuclear Engineering (~800 pers)

• National Institute for Laser, Plasma and Radiation Physics (NILPRP) (~400 pers)

• National Institute of Materials Physics (~200 Pers)

• National Institute for Earth Sciences

• National Institute for Optoelectronics

• Faculty of Physics

UNIVERSITY OF BUCHAREST

Group on Plasma Processes, Materials and Surfaces

Low Temperature Plasma Physics Department

NILPRP

Group on Plasma Processes, Materials and

Surfaces

NILPRP

Topics:

- plasma sources;

- nanomaterials;

- thin films and surface

modification;

- plasma diagnostics

and material

characterization;

Outline

• Motivation

• How plasma works

• Peculiarities of wood processing by plasma

• Plasma sources suitable for wood processing

- low pressure versus atmospheric pressure

- plasma jet sources for material processing

• Examples of processing with atmospheric

pressure plasma sources (polymers)

• Conclusions and perspectivesNILPRP

WOOD: limited service lifetime

• Physical factors:

moisture, temperature

fluctuations, UV-light;

• Chemical factors:

attack by cleaners, acids,

bases, strong oxidants;

• Biological factors:

bacteria, fungi, mold;

dry-rot wood

(humidity, UV)

insufficient wet

adhesion of the

coating

Need of techniques to

protect wood surfaces

moldy wood

due to exposure

to humidityApproaches by plasma techniques

How plasma works

Initial gas +precursor (HMDSO, TEOS)

Radical

flux

Ions

flux

Photon

flux

Ions, e

flux

Bombardment, chemistry:

bond scissions, group attachment

wood piece

Initial gas: Ar, air, N2, O2, He, H2O

Electrons (e) , Ions (Ar+, N2+,O2+), Excited species (Ar*, N2*, O2*, O3);

Radicals, photons (OH, O, N, CN, h )

Radicals: SiOx, C-Si-, -Si-CH3

Electrons (e) , Ions (Ar+, N2+,O2+), Excited species (Ar*, N2*, O2*, O3);

Radicals, photons (OH, O, N, CN, h )

Radical

flux

Ions

flux

Photon

flux

Ions, e

flux

Bombardment, chemistry:

bond scissions, atom removal

wood piece

polar groups, dangling bonds, polar groups, dangling bonds, Coating with a thin film

Wettability increase, etching, reactive

surface for grafting, adhesion, bonding

Film deposition: protective coating,

hydrophobic surface

Plasma processing of wood

Aims:

• Improve the resistance of wood to weathering, erosion under

exposure to UV and moisture conditions; barrier anti-

microorganisms; durability increase.

• Add new functionalities to surface: color, adhesion, glue

ability, or keep natural appearance.

•Solutions:

1. - Surface functionalization by treatment (Ar, N2, O2,

He or mixture): change of roughness, morphology, topography,

chemical moieties at surface, hydrophilic/hydrophobic character;

2. - Surface coating with a thin film (precursors: gaseous

(SF6, C2H2F4), vapor phase (HMDSO), nanoparticles(SiO2);

The problem: to ensure the compatibility of plasma

processing with wood

Peculiarities of wood material and objects

Material peculiarity:- Sensitive to thermal damage;

- Porous and water absorbing;

- Partially conducting.

Size of objects:- Usually large size: specially length, width – meters scale;

- Small features may be present: holes, nuts, gaps –size from a few

millimeters to centimeters.

Shape: flat, but also could be complex: -3D convex surfaces (curved surfaces : plates, rods, bars, etc. );

-3D convex-concave surfaces (objects with inner curvatures).NILPRP

Requirements for plasma sources

Problems related to wood treatment:

- Non-thermal or cold plasmas use (prevent bulk material

degradation, as example by heating);

- Uniform treatment (coat) on large planar surface, or on

complex shape surfaces;

- Ensure the desired properties;

Choices:- Low pressure cold plasma;

- Atmospheric pressure plasma.

Sources design:-In agreement with the

application in view

NILPRP

Low pressure versus atmospheric pressure

plasmas

Low pressure plasma

• Advantages

- plasma is naturally cold, thus reduced

danger of heat damage;

-extends on large volumes;

-plasma generation technology: well-

known.

• Disadvantages

- vacuum technology – difficult with water containing or porous

materials – expensive!

- cannot penetrate in small features as gaps, or holes of the objects;

- processing chambers have limited volume.

Atmospheric pressure - problems

Solutions

• Use of dielectric barriers;

• Keep the system cold:

- Gases with high efficiency of

heat transfer, like helium;

- Use of high gas mass flow rates;

- Control of the power injected in

plasma (ultra short pulsed high

voltages, high frequency, corona,

low RF, DC powers);

-Active cooling of electrodes.Plasma contraction occurs

Appearance of instabilities

High pressure: tendency to arcing (arc discharge);

Pressure

increase

Low pressure: cold plasma

FOCUS ON ATMOSPHERIC

PRESSURE

Plasma sources suitable for wood processing –

atmospheric pressure

Peculiarities:

-Expanding plasmas, or plasma jets:

use of the gas activated in discharge outside

of the inter-electrodic space;

-Remote processing

the sample is placed outside the discharge;

- Radiofrequency generated (13.57 MHz);

- Working gas: argon or nitrogen;

Approach proposed here:

Radiofrequency plasma jet

sources

High

voltage plasma

needle

electrodes

wood

electrode

Corona discharge

High

voltage plasma

wood

Wood as electrode

Dielectric Barrier Discharge

dielectric

electrode

electrode

woodplasma

Type 1 : RF plasma jet sources based on

Discharges with Bare Electrodes (DBE jets)

- principle of operation;

- models;

- some characteristics.

NILPRP

Principle of operation and design

gas in

RF

plasma out

Dielectric

enclosure

nozzledisk

D: 2-10 mm

d: 1- 3 mm

- Argon

- Nitrogen

NILPRP

Surface

Plasma jet

Model 1: hand held, flexible plasma jet source

(20 mm diameter)

- stainless steel body,

- hand held, flexibility for mounting on

robotic arm;

-couplings realized to the back end: RF

power, gas feeding, active water

cooling (2 circuits, inside the RF

electrode and external jacket)

Operation: both in argon an nitrogen

much larger size-length and diameter - in nitrogen

ARGON

NITROGEN

0 1000 2000 3000 4000 5000 6000 7000 8000 9000 100000

50

100

150

200

250

300

350

400

450

500

550

600

650

argon, 2mm interelectrodic distance

Po

we

r (W

)

Mass flow rate (sccm)

Schematic visualization

of the operation domains

nitrogen, 3mm interelectrodic distance

- Higher power values are possible in nitrogen without arcing;

- Longer jets in nitrogen;

-Increased powers ask for increased mass flow rates.

Model 2: Small size, plasma jet source (8 mm

diameter (designed for low power, no cooling)

Requirements:AIM: surface

modification

of polymers

-Small size

-Flexible

-Low power

-Low temperature

Temperature (thermocouple)

PARAMETERS:

• RF power: 15-25 W

• Gas : Ar, Ar/O2

• Mass flow rates: 2000-4000 sccm

• Plasma jet diameter: 0.5 -1mm

(depends on conditions)

• Plasma jet length (1-10 mm),

depends on gas, power, flow rate

OTHERS:

• Breakdown at atmospheric pressure

• Grounded, not danger of electric

shock

14 15 16 17 18 19 20 21 22 23 24 2530

40

50

60

70

80

90

100

110

Te

mp

era

ture

[oC

]

Power RFfwd

[W]

Dependence of gas temperature upon

forwarded power , for the settings: argon

gas, 4000 sccm, 1 mm from nozzle

Type 2: Expanding RF jet sources based on

dielectric barrier discharges (DBD jets)

designs and models

DBDs jet sources designs

CERAMIC

MATERIAL

GAS

TEFLON

ADAPTER

TEFLON

SPACERS

UPPER

ELECTRODE

RF

GROUNDPLASMA

L=60

mm

a)two

barrie

rs

d=1mm

TEFLON ADAPTER

GAS

TEFLON

SPACERS

UPPER

ELECTRODE

RF

GROUNDPLASMA b)

d=1mm

CERAMIC

MATERIAL

GROUND

GAS

TEFLON

ADAPTER

GROUND

ELECTRODE

DISCHARGE

SPACE

UPPER

ELECTRODE

CERAMIC

MATERIAL

RF

PLASMA

d1=1mm

L=60

mm

c)

d)

UPPER

ELECTRODE

(RF)GAS

CERAMIC

SPACERS

RF

PLASMA

d=1mm

LOWER

ELECTRODE

(GROUND)

CERAMIC

BARRIER

a) parallel rectangular double-barrier configuration, b) parallel rectangular single-barrier

configuration, c) non-parallel double-barrier configuration and d) parallel trapezoidal

single-barrier configuration.

Images of various DBD jet configurations

Single barrier plan parallel

rectangular configuration,

expansion through mesh

Angled parallel single

barrier configuration

Double barrier plan

parallel rectangular

configuration

Single barrier plan

parallel rectangular

configuration

Reactive species - expansion

in open atmosphere

200 300 400 500 600 700 800 900 10000

500

1000

1500

2000

2500

3000

3500

4000

4500

ArI

OI

OH

2ndOrder NO

2nd OrderN

2

N2

N2

N2, NH

OH

Wavelength (nm)

Ar 500sccm, Prf=50 W

NO

OI

Optical emission spectrum recorded

in the front of the parallel DBD

(Ar lines, N2, NH, OH molecules)

Plasma rich in active species-

radicals: oxygen, hydroxyl, etc.

304 305 306 307 308 309 310 311 312 313 314 315

0

2000

4000

6000

8000

10000

12000

14000

16000

Trot=364K

OH

A2 +

-X2

Inte

nsity [a.u

.]

Wavelength [nm]

Experimental spectrum

Simulated spectrum

Simulation of OH bands (small size

jet at 15W and 5200 sccm gas flow, 1

mm from nozzle)

Temperatures (by thermocouple)

0 1 2 3 4 5

30

40

50

60

70

80

90

100

Tem

per

atu

re [

0C

]

d [mm ]

Temperature distribution

perpendicular on the flow

axis ( 2 mm from nozzle)

0 2 4 6 8 10 12 14 16 1830

40

50

60

70

80

90

100

Tem

per

atu

re [

0C

]

d [mm]

Temperature distribution

along the flow plane

(central position)

Cleaning: organic or carbon residuals

removal from surfaces at atmospheric

pressure

- Surface scanning;

-Carbon layers removal from flat surfaces

Plasma cleaning: removal of carbonic

(organic layers) from flat surfaces

Layer thickness: 1 m

Number of scans: 1

Power: 350 W

Nitrogen, mass flow rate: 7500

sccm

Carbon films, thickness: 1-10 m

Substrate: silicon, 2 m

Modification of wettability of polymeric

surfaces at atmospheric pressure

- scanning the surface with the cold plasma jet

A) - measurement of the contact angle after various number of scans;

B) - Illustration of the wettability change: different drop shapes of water by

vapor condensation on the cooled treated PET surface;

C) -patterning surfaces with wettable traces

A. Decrease of the contact angle on PET

surface after scanning

gas: Ar

mass flow: 3000 sccm

power: 16W

temperature : 42oC

scanning speed: 5mm/s

0 2 4 6 8 10

30

40

50

60

70

80

conta

ct

angle

[deg]

number of scans

10 mm

1

0

m

m

1 mm

The scanning path on

the probe

B. Water vapor condensation

In the marked square half of the area

is treated and half is untreated

Cold substrate

holder (Peltier)

PET foil

Detailed view of the border between

untreated and treated zones

B. Water vapor condensation

treated untreated

Cold substrate

holder (Peltier)

PET foil

Detailed view of the border between

untreated and treated zones

Adhesion test (scotch test) on plasma

modified surfaces

0 100 200 300 400 5000.0

0.5

1.0

1.5

2.0

2.5 PET

PTFE

PE

F [

N]

Numar scanari

Results of the adhesion test Measurement of the detachment

force

F=mg

Foil surface

Scotch tape

Detachment force: dependence

upon the number of scans

Modification of wettability of polymeric

surfaces with a DBD jet

Procedure - scanning the surface with the cold

expanding DBD plasma

A) - measurement of the contact angle after various number of scans;

B) - Illustration of the wettability change: different drop shapes of water

by vapor condensation on the cooled treated PET surface;

C) -patterning surfaces with wettable traces

Treatment of polymeric surfaces

10 mm

10

mm

1 mm

The scanning path on

the probe

RF

Computer

interface

Travel stage X-Y

Y Movement

X MovementPlasma source

holder

Sample

DBD

Plasma

Source

Gas

PET and PVC foils of 10 by

30mm have been scanned

on a area of 10x10mm.

Image of the plasma jet

during PET treatment

Wettability improvement and ageing study

0 10 20 30 40 5020

30

40

50

60

70

80

90

100

110

120

Co

nta

ct a

ng

le [

deg

rees

]

Number of scans

in 1'st day

after 9 days

after 21 days

PE

0 10 20 30 40 5010

20

30

40

50

60

70

80

90C

onta

ct a

ng

le [

deg

rees

]

Number of scans

in 1'st day

after 22 days

after 34 days

PET

0 10 20 30 40 5020

30

40

50

60

70

80

90

100

110

120

Co

nta

ct a

ng

le [

deg

rees

]

Number of scans

in 1'st day

after 17 days

after 29 days

PVC

0 10 20 30 40 5020

40

60

80

100

120

Co

nta

ct a

ng

le [

deg

rees

]

Number of scans

in 1'st day

after 4 days

PTFE

Patterning of surfaces

Drops array: condensation of the

water is enhanced on the treated

surface of the polymer

Image of mask, which is placed

between plasma and surface

(holes: 100 microns).

Conclusions and perspectives

NILPRP

• Versatile RF plasma jet sources at atmospheric pressure of various sizes, powers are available;

•Operation in argon and nitrogen;

•Temperature controlled by power, mass flow rate;

•They are sources of reactive species;

•Effective surface modification of polymers at atmospheric pressure;

• Treatment of gaps and voids possible;

•Suitable for downstream precursor injection: deposition;

•Up-scale easily possible for the DBD jets

Thank you for your attention !