What is Atomic Layer Deposition (ALD)?

As components get smaller, particularly in the electronics industry, innovative coating methods are required that can deposit coatings which are homogenous, highly uniform, dense, conformal, and virtually free from defects, like pinholes.

Please welcome Atomic Lay Deposition to the stage!

What is Atomic Layer Deposition?

As the name implies, atomic layer deposition (ALD) is the deposition of thin-film layers at the atomic level. ALD allows films to be built layer by layer with unparalleled uniformity at thicknesses measured in nanometers. This ability opens an exciting new world of application from microelectronics to wear resistant coatings. ALD has helped facilitate the continued miniaturization and enhancement of devices and components we depend on daily.

This video offers a super, in-depth exploration of the intricacies of ALD technology. By the way, it's really long.

Benefits of Atomic Layer Deposition

Uniformity

Conformity

Ability to coat complex 3D components or structures

ALD does not require line-of-sight like PVD

Tailorable

Films can be engineered to exhibit desired properties, enhancing the component to which the film is applied

Scalable & Repeatable

Ultra-thin

ALD films are measured in nanometers

Low Process Temperatures

Allows the use of sensitive substrates like plastics or papers

Self-limiting

Self-limiting surface reactions result in negligible pinhole defects and a monolayer film

Example Process using Atomic Layer Deposition

Atomic Layer Deposition process steps - Step 1

First Gas, Precursor A, is Introduced

Atomic Layer Deposition process steps - Step 2

Excess Precursor A is Purged

Atomic Layer Deposition process steps - Step 3

Second Gas, Precursor B, is Introduced

Atomic Layer Deposition process steps - Step 4

Excess Precursor B is Purged

What's the Catch?

While Atomic Layer Deposition has many upsides and growing, there are a couple of caveats to be aware of.

One drawback is that the Atom to be deposited needs to be package in a precursor. This makes proper precursor selection essential.

Another drawback and possibly the most important is the speed at which layers can be built up. A deposition speed of < 1 Angstrom / second is typical. For comparison, your hair grows at an average rate of 46 angstroms / second.

Applications

Microelectronics

Biomedical

Aerogels

Energy Storage

Nanostructures

Corrosion Resistant Coatings

Wear Resistant Coatings

Solar Cell Technologies

Chemical Sensors

Recyclable Packaging

The practical applications for atomic layer deposition technology are almost limitless. Here at UPT we are always pushing the boundaries of technology and have developed a new proprietary coating using a hybrid coating technology, which involves ALD.

Adsorption

Let's get into the weeds, so to speak. Adsorption is the mechanism used in Atomic Layer Deposition and is the interaction between an adsorbing molecule, the precursor, and a solid surface, the substrate. There are two types of adsorption, Physisorption and Chemisorption. An understanding of adsorption mechanisms is critical when developing thin films using Atomic Layer Deposition. While either may be used, Chemisorption is preferred, and you'll see why below.

Physisorption

Weak interactions, Van der Waals forces
Reversible
Interactions are NOT specific, resulting in multilayer formation.
Only occurs at low temperatures

Chemisorption

Chemical bond formed
Strong Interactions
Irreversible
Interactions are specific, which makes them self-limiting, resulting in monolayer formation.
Can occur at all temperatures

Typical Materials deposited with ALD

Customization of the individual layers can result in some fantastic properties, unachievable through traditional production technologies.

Oxides
Nitrides
Flourides
Sulfides

Pure Metals
Polymers
Graded, Mixed, or Doped Layers

ALD Coating