Table 1. Microfabrication techniques used for the primary patterning of nanostructures.
Note: relevant exemplars from the literature are cited against each technique. The minimum feature size and length of patternable area are highly equipment and facility dependent, these values are derived from the either manufacturer provided specifications at the time of writing, or from the literature, where available. Techniques are sorted loosely by their prevalence within the field, with the most common listed first. Most fabrication protocols include a combination of techniques, here we are referring to the process used to define the initial pattern.
| Technique | Example applications | Minimum feature size [μm] | Diameter of patternable areaa) [mm] | Advantages | Disadvantages |
|---|---|---|---|---|---|
| Photolithography | Nanoneedles,[26,69,133] hollow nanoneedles/ nanotubes,[134,135] nanowires,[136] | ~0.6 – 3[137] | ≥300 (typically ≥100)[137] | Good resolution | Equipment expensive |
| Parallel patterning | Tooling expensive and unmodifiable | ||||
| Well-established industry process | Complex protocols | ||||
| Sub-micron resolution challenging to achieve in many system | |||||
| Electron-beam lithography | Nanowires,[138,139] nanopillars,[31] nanostructures,[140,141] nanopits / nanopores,[142,143] nanoelectrodes,[28,66,86,144] | ~0.04 – 0.5[145] | ≥300 (in theory, but in reality individual field size ~1 1)[146] | Best resolution | Expensive equipment |
| Flexible design (no fixed tooling required) | Very slow, effectively limiting patternable area | ||||
| Complex protocols | |||||
| Limited resist choices | |||||
| Track-etched membrane / nanopore templates | Nanoelectrodes,[147] spiky microstraws,[94] nanopillar arrays,[148] nanostraws,[90,91] | ~0.1[89] | ≥100[89] | Templates are highly affordable | Limited or no control over location of individual pores |
| Large patternable areas | |||||
| No cleanroom required | |||||
| Nanoimprint lithographyb) | Nanowires,[149] nanopillars,[148,150] nanostructures.[151] | ≥0.04[153] - 25 | ≥150[153] (very large area roll-to-roll patterning reported)[151] | Parallel / quick patterning process | Requires expensive master stamp / shim |
| Good resolution | Care required to optimize resist and surface treatments to ensure good demolding | ||||
| Excellent for reproducing existing designs | |||||
| Very large area patterning possible | |||||
| Nanosphere / colloidal lithography | Nanowires,[27,154,155] nanoelectrodes,[136] nanopillars.[156] | ~0.1 – 2[157,158] | 1×103 (areas of up to 1 m2 reported)[158] | Affordable method | Challenging to align patterns to existing features |
| Achievable with relatively simple equipment | |||||
| Strong interdependence between patterned particle and spacing | |||||
| Very large area patterning possible | |||||
| Ion-beam lithographyc) | Nanoelectrodes,[62] nanoantennas,[159] nanotubes.[92] | ~0.02 – 0.5[160] | ~2.5[160] | High precision | Expensive equipment |
| Best resolution | Very slow, effectively limiting patternable area | ||||
| Interference lithography | Nanostructures;[161] nanoposts.[162] | ~0.05 – 0.5[163] | ≥200[163] | Good resolution | Limited design choices as pattern must be formed by interfering beams |
| Relatively large areas possible | |||||
| Specific tooling required | Requires relatively specialist setup | ||||
| Parallel processing | |||||
| Two-photon / multiphoton lithography | Nanopillars / ridges,[124,164] microneedles.[165] | ~0.15 – 10 (2D patterning, in 3D resolution is lower)[166] | ≥100 (individual field size ≥1)[166] | Good resolution | Expensive equipment |
| Flexible design (no fixed tooling required) | Highest resolution only possible in 2D, 3D structures more typically in micron scale | ||||
| Slow, hence limited write areas | |||||
| Electroless depositiond) | Nanowires.[167,168] | ~0.1 – 0.2[167–169] | ≥100 (limited by wafer handling for acid etching) | Highly affordable | Stochastic – limited control over pattern density and size of features |
| Achievable in chemistry lab, no cleanroom required | Challenging to align to existing features | ||||
| Deposition of particulates from gas phase (e.g. aerosol deposited nanoparticles or sputtering)d) | Nanowires,[170,171] nanoneedles.[29,81] | ~0.04 – 0.1[170,171] | ≥100 (assuming wafer-based system) | Can be performed in-situ with growth mechanisms for efficient processing | Stochastic – limited control over pattern density and size of features |
| Challenging to align to existing features | |||||
| Direct (write) laser lithography | Nanoneedles[172] | 1 – 50[173] | ≥100[173] | Flexible design (no fixed tooling required) | Compromise on resolution due to larger laser beam spot size |
| Typically easier to pattern large areas (e.g. whole wafers) compared to multiphoton approaches | Requires relatively specialist equipment | ||||
This is an estimate of the reasonable diameter over which a given technique can be used to define a pattern, assuming a circular write field;
nanoimprint lithography requires a master stamp (also known as a shim) to define the pattern being imprinted. This stamp is frequently fabricated by other techniques, such as electron-beam lithography;
this refers to using a focused-ion beam microscope to selectively mill (or deposit) a pattern of nanostructures;
these techniques, while mainly used to deposit material and turn 2D structures into 3D, can also be used to define an initial pattern through the stochastic / partial deposition of another catalytic material onto a surface, which is subsequently used as a seed for further growth.