ConductLayer

XSEC-001

12s LOOP

SCALE 1:50,000

Textile Electroplating Facility · EST. 2009

Seven layers.
Fourteen chemistry
stages.
One fabric.

Copper bonded to polyester at the atomic level. Defense-grade EMI shielding, heated garment layers, and biocompatible conductive wound dressings — built to your exact specification.

Defense / EMI ShieldingWearable-Tech PrototypingMedical Device — ISO 10993MIL-STD-461 Certified

Chemistry Stages

per production run

Deposited Layers

base to topcoat

0.3 µm

Cu Deposit Tolerance

±0.05 µm

72 dB

SE @ 1 GHz

MIL-STD-461 verified

Scroll Process

Process Architecture

6 STAGES · 14 BATHS

STAGE 01·PT-01

Pre-Treatment

Surface preparation & organic removal

Every substrate enters a 3-bath alkaline cleaning sequence. Oils, sizing agents, and atmospheric contaminants are stripped to a contact angle below 20°. A substrate that isn't atomically clean at this stage will produce adhesion failures three layers later — this is where tolerances are either established or destroyed.

PT-01·Pre-Treatment

LIVE

Bath Temp

60°C

Range: 55–65°C

Soak Time

8min

Range: 6–12 min

11.2

Range: 10.8–11.8

Detergent Conc.

12g/L

Range: 10–15 g/L

Bath 1

Alkaline Degreaser

TEMP

60°C

TIME

3 min

Removes oils & waxes

Bath 2

Anionic Surfactant

TEMP

55°C

TIME

3 min

Lifts fiber sizing

Bath 3

DI Water Rinse

TEMP

20°C

TIME

2 min

Zero-conductivity rinse

PT-01 Output vs. Industry Pre-Treatment StandardsConductLayer vs. Industry

Metric	ConductLayer	Industry Avg.	Unit
Contact angle post-clean	< 20°	25–40°	°
Residual organic contamination	< 0.5	1.5–3.0	mg/m²
Surface roughness (Ra)	180–220	300–500	nm
Process repeatability (σ)	< 2.1	5–8	%

STAGE 02·AC-02

Activation

Palladium-tin catalyst seeding

Palladium-tin colloidal catalyst is adsorbed onto the cleaned fiber surface. The Pd²⁺ ions form the catalytic seed layer that will initiate electroless copper reduction in Stage 3. Seed density directly determines copper nucleation uniformity — at 1.8×10¹⁴ atoms/cm², we achieve a continuous film rather than isolated islands.

AC-02·Activation

LIVE

Pd Conc.

0.18g/L

Range: 0.15–0.22 g/L

Sn²⁺ Conc.

14g/L

Range: 12–18 g/L

Bath Temp

30°C

Range: 25–35°C

1.8

Range: 1.5–2.2

AC-02 Seed Density vs. Industry Activation PerformanceConductLayer vs. Industry

Metric	ConductLayer	Industry Avg.	Unit
Pd seed density	1.8×10¹⁴	0.9×10¹⁴	atoms/cm²
Activation uniformity	< 3.2	8–15	% CV
Accelerator bath life	420	200–280	cycles

STAGE 03·ED-03

Electroless Deposition

Autocatalytic copper reduction

In an alkaline formaldehyde-reducing bath, copper ions are reduced onto the palladium seed layer without external current. The reaction is autocatalytic — once started, the copper surface itself catalyzes further deposition. Controlling pH to ±0.2 units at 42°C is the single most critical variable in this stage; drift produces void formation and resistivity spikes.

ED-03·Electroless Deposition

LIVE

Cu²⁺ Conc.

3.2g/L

Range: 2.8–3.8 g/L

Formaldehyde

8mL/L

Range: 6–10 mL/L

Bath Temp

42°C

Range: 38–46°C

12.4

Range: 12.0–12.8

Critical Parameter Alert

pH window: 12.0–12.8

Outside this window: below 12.0 → bath decomposition; above 12.8 → co-deposition of Cu₂O inclusions raising resistivity 18–40%.

Current pH

12.4

NOMINAL

ED-03 Deposit Quality vs. Electroless Industry BenchmarksConductLayer vs. Industry

Metric	ConductLayer	Industry Avg.	Unit
Deposition rate	2.4	1.2–1.8	µm/hr
Copper purity	99.4	96–98	% Cu
Void density	< 0.3	2–8	voids/cm²
Thickness uniformity	2.8	8–14	% CV

STAGE 04·EP-04

Electroplating

Nickel overplate for durability & corrosion resistance

The electroless copper layer (0.3–0.8 µm) is overplated with electrodeposited nickel to 1–3 µm. Nickel provides corrosion barrier, hardness (520 HV vs. copper's 80 HV), and maintains shielding effectiveness through wash cycles. Current density at 2.4 A/dm² produces a fine-grained deposit; exceeding 3.5 A/dm² causes burning at fiber crossover points.

EP-04·Electroplating

LIVE

Current Density

2.4A/dm²

Range: 1.5–3.5 A/dm²

Ni²⁺ Conc.

82g/L

Range: 75–90 g/L

Bath Temp

52°C

Range: 48–58°C

Plating Time

18min

Range: 12–25 min

EP-04 Plated Performance vs. Competitor Final ProductsConductLayer vs. Industry

Metric	ConductLayer	Industry Avg.	Unit
Surface resistance	0.042	0.12–0.25	Ω/sq
Shielding effectiveness (1 GHz)	72	45–58	dB
Nickel layer hardness	520	380–440	HV
Tensile strength retention	97	82–90	%

STAGE 05·QA-05

Quality Assurance

100% lot testing — no sampling protocols

Every production lot undergoes full four-point probe resistance mapping (25 measurement points per 1m² panel), ASTM D3359 adhesion tape test, and shielding effectiveness measurement per IEEE 299-2006. Medical-grade lots additionally undergo ISO 10993-5 cytotoxicity evaluation. We publish raw test data with every shipment.

QA-05·Quality Assurance

LIVE

Sheet Resistance

0.042Ω/sq

Range: < 0.05 Ω/sq

Adhesion (ASTM)

Range: ≥ 3B

SE @ 1 GHz

72dB

Range: ≥ 65 dB

Thickness CV

2.1%

Range: < 5%

MIL-STD-461G

EMI/EMC Shielding

ISO 10993-5

Biocompatibility

IEEE 299-2006

SE Measurement

ASTM D3359

Adhesion Testing

RoHS 2.0

Material Compliance

REACH SVHC

Chemical Safety

QA-05 Compliance Rates vs. Industry Testing StandardsConductLayer vs. Industry

Metric	ConductLayer	Industry Avg.	Unit
MIL-STD-461 pass rate	99.2	87–92	%
ISO 10993-5 cytotoxicity	Grade 0	Grade 1–2	grade
Wash durability (cycles)	> 100	30–60	cycles
Lot-to-lot resistance variance	< 4	12–22	%

STAGE 06·FN-06

Finishing

Protective topcoat application & cure

A 2–4 µm fluoropolymer or polyurethane topcoat is applied by pad-mangle and cured at 120°C. The topcoat maintains surface resistance below 0.05 Ω/sq while providing 500+ hour salt spray resistance (ASTM B117). Topcoat chemistry is selected based on end-use: PTFE-based for medical, PU for defense, silicone-hybrid for high-flex wearable applications.

FN-06·Finishing

LIVE

Topcoat Thickness

3.2µm

Range: 2–4 µm

Cure Temp

120°C

Range: 110–130°C

Cure Time

22min

Range: 18–28 min

Salt Spray (hrs)

500h

Range: ≥ 480 h

Medical Devices

PTFE-Based

Low flex

ISO 10993 compliant, zero cytotoxicity

Defense / EMI

Polyurethane

Medium flex

MIL-STD-810 environmental

Wearable Tech

Silicone Hybrid

High flex (>50k cycles)

Maintains SE after repeated bending

FN-06 Final Product Performance vs. Industry Finished GoodsConductLayer vs. Industry

Metric	ConductLayer	Industry Avg.	Unit
Salt spray resistance	500+	200–350	hours
Topcoat adhesion (ASTM D3359)	5B	3B–4B	grade
Post-finish sheet resistance	0.048	0.15–0.30	Ω/sq

Supplier Comparison Tool

Compare Against Your Current Supplier

Enter your current specification on the left. Our guaranteed performance range auto-populates on the right. If the numbers don't beat your current supplier, we'll tell you directly.

Process Documentation

Download Full Process Spec Sheet

47 pages. Every bath formulation, operating window, control parameter, and test method. The same document we hand to defense procurement officers and FDA submission teams.

Complete bath chemistry formulations

Statistical process control charts (12-month data)

MIL-STD-461G test reports

ISO 10993-5 biocompatibility certificates

Lot traceability methodology

Company email required — no personal addresses

Seven layers.
Fourteen chemistry
stages.
One fabric.

Pre-Treatment

Activation

Electroless Deposition

Electroplating

Quality Assurance

Finishing

Compare Against Your Current Supplier

Your Current Spec

ConductLayer Guaranteed Range

Download Full Process Spec Sheet

Seven layers. Fourteen chemistrystages.One fabric.

Pre-Treatment

Activation

Electroless Deposition

Electroplating

Quality Assurance

Finishing

Compare Against Your Current Supplier

Your Current Spec

ConductLayer Guaranteed Range

Download Full Process Spec Sheet

Seven layers.
Fourteen chemistry
stages.
One fabric.