For centuries, printing of texts and graphics on flat (two-dimensional) substrates such as textiles and paper has been an essential enabling technology for the cultural development of mankind. Only recently has this technique been considered as a valuable tool for the processing of functional nanomaterials, for example, in the electronics and biomedical industries [1–6]. For electronics manufacturing, for example, printing has some decisive advantages compared with the more traditional approaches of semiconductor processing. First of all, printing is an additive process, meaning that functional materials are deposited only where needed and can be used much more efficiently than with subtractive techniques, which tend to produce a lot of waste [7, 8]. In addition, printing can be carried out at atmospheric pressure, making high-vacuum technologies obsolete, which also contributes to significant savings on production costs. A third advantage is the selectivity of printing, making multimaterial applications such as multicolor lighting [9–11] or printed thin-film transistors [12, 13] possible. Since in the graphics printing industry, many 2D printing technologies have already been developed toward roll-to-roll processing, commercial mass production of nanomaterial-based printed electronics devices in a continuous manufacturing mode is also within reach [14–16].

A wide variety of 2D printing technologies has been applied for the processing of functional nanomaterials, which can be subdivided into two different groups: noncontact or digital (maskless) printing technologies (without physical contact between printing equipment and substrate) and contact (mask-based) printing technologies (with physical contact). In noncontact printing, droplets or jets of the functional ink are generated at a (small) distance from the substrate and transferred onto it by a pressure pulse that propels them across the interspace. Contact printing typically makes use of a predetermined pattern, embedded as a mask in a drum or screen, which is repeatedly replicated on the substrate by directly touching it. Typical examples for noncontact techniques are inkjet printing (IJP) and laser-induced forward transfer (LIFT), and examples of contact technologies are offset, flexo, gravure, screen, and microcontact printing.

In general, critical issues to be considered during the choice for a specific printing technology for functional nanomaterials are technical aspects such as resolution, feature definition, adhesion, process reliability and stability, manufacturing speed, and device performance. Also nontechnical process features such as production volume and cost, environmental impact, and operator and customer safety are important, since all of these combined will determine whether printing will be a technically and economically viable option for a specific type of device. Since functional electronic and biomedical devices are frequently composed of complex ultrathin stacks of various (nano)materials, some of which can be highly sensitive to mechanical pressure, contactless printing can be a decisive advantage [17]. The balance between design flexibility and the potential for mass manufacturing is another consideration. Digital printing technologies offer a lot of design freedom and easily allow for image adjustments to compensate for possible substrate deformations (for instance, in the case of flexible or stretchable substrates [18]). However, productivity should come from mass parallelization with the obvious challenges such as yield, stability, reproducibility, and durability.

By contrast, all contact printing techniques involve some kind of physical stencil that determines the printing pattern and needs to be adjusted every time a different image is to be produced. This feature, in combination with its potential for very-high-throughput production, makes many contact printing techniques especially suited for the production of large numbers of identical devices [15]. In mature industrial production processes, contact printing is therefore usually preferred, unless possible damage to the products by mechanically touching the surface prohibits its use. By contrast, noncontact processes are generally the technology of choice where small series are required, such as in many academic research laboratories and in early-stage industrial research and development. However, the potential for scalability or transfer to other processes, which are more adept for mass production, is required for the latter to be of any practical use.

In addition to nanomaterials' deposition in two dimensions on flat substrates, functional printing has recently also been applied for the construction of three-dimensional objects [6, 19, 20]. 3D printing or additive manufacturing (AM) is known as a layer-by-layer manufacturing technology to build 3D products. In analogy to 2D technologies, it is an enabling approach with numerous advantages compared with the conventional (subtractive) manufacturing technologies. AM enables the cost-effective manufacturing of complex, personalized, and customized products. It also offers the possibility to introduce multimaterial products or parts with material gradients [21]. AM integrates very well with design tools and computer-aided design (CAD) software and as a result, the AM approaches can significantly impact both time and cost savings, as well as inventory, supply chain management, assembly, weight, and maintenance. AM is seen as an enabling technology for many applications, such as embedded and smart integrated electronics (Internet of things, smart conformal and personalized electronics [22]), complex high-tech (sub)modules made of ceramic or metal with multimaterial or grading material properties [23], and human-centric products (e.g., dentures, prostheses, implants [6, 24]). While new materials and manufacturing technologies are introduced in the market, we see that for many applications the technology is still immature: product quality is inferior to that obtained with conventional methods, the choice of available materials is limited, yield is low by process-induced defects, manufacturing costs are high, and productions speeds are typically low [25].

3D printing comes in various embodiments. Selective deposition techniques, such as viscous jetting, fused deposition modeling, cladding, or wire feed are well-known technologies based on the consecutive deposition of a printable/processable (nano)material to build layer-by-layer the 3D product. The product definition is determined by the spatial deposition and the dimensional stability of the deposited material (the material needs to have fluidic properties during the release from the reservoir or nozzle to print but should have (rigid and) superior material properties in the final product), and the patterning resolution of the deposition heads. The other class of AM technologies is based on pattern definition with an external source (e.g., laser beam or E-beam) in a homogeneous layer of material. During each print step, a homogeneous layer of material is deposited, but only the fraction that constitutes the final product is fused to the part via a sintering process (selective laser sintering (SLS)), melting process (selective laser melting (SLM)), binder jetting process, or photopolymerization process (stereolithography (SLA), vat photopolymerization). This family of AM technologies comes often with a higher spatial resolution but frequently suffers from inferior material properties (porosity in SLS, defects in SLM, uncured monomers and inferior material properties in vat). Emerging technologies are combinations of these: two-photon, reactive jetting, conformal printing, and so on.

The current focus for metal AM is on monomaterial technology improvement to enable lightweight parts for space, aerospace, and automotive applications and customized parts for medical and high-tech. The currently utilized processes are mainly based on cladding or selective melting (with laser or e-beam) to make metallic parts from powder. Challenges include the avoidance of thermally induced stresses that give rise to warpage and mechanical deformation, homogeneity and purity of the printed part, and defectivity control (e.g., small defects might result in fatigue challenges).

The currently utilized technology for ceramics parts is selective sintering: the fusion of ceramics particles under the influence of heat or photopolymerization based on a polymer binder system, in which a ceramics powder is dispersed. In both cases, the final ceramic product is preferably 100% pure and does not comprise contaminants of the binder.

Nanomaterials are typically used in both 2D and 3D printing to add functionality to the polymer or multimaterial systems. Nanomaterials can be added to a polymer system to improve material properties (e.g., mechanical strength, color, flame-retardation ability, biocompatibility), or to create anisotropy (via fibers, filaments, nanotubes, etc.). Examples include the addition of clay particles to photoresins to improve the mechanical properties such as impact strength and biocompatibility for use in high-tech engineering. Another example is the addition of metal compounds, such as metal nanoparticles, to make conductive tracks in free-form electronics applications.

The core ingredient of an electronic or biomedical ink is the functional nanomaterial to be deposited. Since a detailed overview is presented in Chapters 7–14, here only a brief summary is given. A wide variety of nanomaterials with all kinds of properties and shapes have been formulated into inks and pastes. Examples include conductive [26], semiconductive (e.g., electroluminescent or photovoltaic [27]), or piezoelectric [28] as well as catalytically and biologically active materials [29]. Also the dimensions of the materials used cover the entire range defined for nanotechnology from the sub-nanometer regime up to fractions of a micrometer. “...