Abstract
Precise control of the life cycle of materials has become critical. Long-lasting materials are not always the best—for example, nondegradable plastic waste is now a serious environmental problem. Transient electronic devices have a prescribed life cycle in which all or part of the device can physically dissolve, disappear, or degrade after their utility ends. This concept creates compelling opportunities for biodegradable temporary, implantable electronics that do not require removal; environmentally benign biodegradable electronics with zero waste; and security hardware with on-time system destruction. Nanoscale materials provide new uses for transient materials dissolution by scaling up the rate of degradation; for example, a microscale Si single crystal is not dissoluble, but at around 100 nm, the Si single crystal dissolves in approximately one month. Significant advances have been made in exploring transient, water-soluble, and biodegradable nano-/micromaterials, and their degradation chemistry and kinetics. Advancing the state of the art in transient electronics requires contributions from many disciplines of materials science ranging from materials analysis to applications. This article outlines the history of transient electronics and briefly overviews concepts and issues from inorganic- and organic-based electronic materials, process technology, and energy devices to trigger transient electronics.
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Introduction
Electronic devices providing extensive functionality and tremendous convenience have become essential in society today. The demand for stable, long-operating electronic devices has long motivated studying their reliability. In 2012, a new type of electronics with a goal antithetical to conventional reliability emerged under the name “transient electronics”—electronic devices that disappear within a specified time frame.1
Transient electronics offer new opportunities in applications in alternative and emerging fields that previous permanent electronics cannot achieve. For example, a biodegradable electronics device can be implanted inside the body to diagnose and treat patients without needing surgical removal after its function ends, thus reducing the risk of surgical accidents and infection.2–5 It also provides waste-free technology—the device self-degrades into eco-compatible, easily disposable byproducts, and is thus attractive for wearable and patch-type electronic devices.1,6 This type of electronics offers hardwarelevel security by self-destruction on demand of specified areas such as memory so as not to expose unwanted information and device features.7–10
The history of general transient materials has its roots in biodegradable materials. Biodegradable materials have been widely used, including medical sutures, polymer scaffolds for tissue regeneration, metals and alloys for temporary bone joints or stents to minimize restenosis, active glass to promote bone regeneration, and as vehicles for drug delivery.11,12 Most applications, however, have been limited to using structures or biochemically reactive species; advanced functions such as comprehensive sensing and delicate treatment were not yet possible. The first study exploring biodegradable electronics entailed constructing an organic thin-film transistor using biodegradable semiconducting and dielectric materials.13 A subsequent study expanded the biodegradable electronic materials possible by adopting natural chemicals such as indigo, yellow G, and indanthrene, and synthesizing artificial polymers such as poly(diketopyrrolopyrrole- p-phenylenediamine) (PDPP-PD).14,15
Hwang et al. reported outstanding results in transient electronics in 2012 that suggested that electronics-grade single-crystal Si in nanometer-scale membrane form dissolves within a reasonable time frame (on the order of a few to 10 nm per day) in a phosphate buffer solution (PBS).1 They created fully functional electrical components, ranging from active transistors and diodes to passive inductors and capacitors, using single-crystal Si nanomembrane semiconductors, SiO2 and MgO dielectrics, and Mg electrodes on biodegradable silk substrates. In addition, they showed that all of these electronics are dissoluble. This study laid out the concept of transient electronics and also pointed to the possible translation of conventional Si-based electronics to water-soluble transient electronics such as semiconductors, piezoresistivity sensors, photovoltaic energy harvesters, and photoconductive sensors.1 The transient electronic devices now available range from metal oxide semiconductor field-effect transistors (MOSFETs), complementary metal oxide semiconductors (CMOSs), and logic circuits to sensors for temperature, strain, pressure, thermodiffusion, and flow rates.1,2,6,16
The potential uses of transient electronics have already been demonstrated in biodegradable devices with clinically relevant medical applications. A medical device has been proposed to diagnose traumatic brain injury, which has an incubation period and thus requires temporary monitoring of intracranial pressure.2 Fully biodegradable, miniaturized pressure sensors have been made of nanoporous Si for rigid volumetric structure, biodegradable poly(lactic-co-glycolic acid) (PLGA) for flexible membranes responsive to external pressure, Si nanomembranes for strain sensing, and SiO2 for the encapsulation layer. The pressure sensor delivered continuous monitoring of intracranial pressure in a rat model with a wireless interface. These results validate biodegradable electronics in animals at clinically acceptable performances. Subsequent research on measuring electroencephalography (EEG) and electrocorticography (ECoG) also supports the effectiveness of transient electronics.3 A biodegradable wireless stimulator has recently been used therapeutically to accelerate the regeneration of function of injured peripheral nerves, thus extending the use of transient electronics from sensing to therapy.4
The development of transient electronic devices requires research in all areas of materials science and engineering, including analysis of material behaviors, development of process and fabrication technologies, and verification and application in devices, and on a system level Figure 1 A database of transient organic and inorganic materials (Figure 1a) has been established from dissolution mechanism studies of potential materials, including dissolution chemistry and kinetics under various environmental conditions (temperature, pH, and other ion species in fluids).1,17–20 Accurate control of lifetime is available by passively protecting the device with biodegradable encapsulation or actively initiating the degradation reaction by triggering (Figure 1b). Fabrication strategies such as transfer-printing and solution-printing processes (Figure 1c) are also being widely developed for integrated transient electronic materials, from the component level to circuit and systemlevels (Figure 1d).16,21,22 Results have yielded various devices for measurement, logic processing, and activation of biomedical and eco-friendly sensors and actuators such as intracranial pressure monitor, environmentally friendly stimulator, and a wireless self-destructive heater (Figure 1e). Applications continue to expand.1–6
Representative research areas of transient electronics in materials science and engineering, (a) Dissolution chemistry studies in inorganic and organic electronic materials. Adapted with permission from References 1 and 15. © 2012 AAAS and 2017 Proceedings of the National Academy of Science, respectively, (b) Lifetime controlling method using passive encapsulation and active triggering. Adapted with permission from References 7 and 17. ©2014 Wiley, (c) Fabrication strategy of transient electronics using solution processing for a wafer-scale approach. Adapted with permission from References 21, 25, and 22. © 2014 Wiley and 2017 Proceedings of the National Academy of Science, respectively, (d) Example of transient device formed from electric components (array of metal oxide semiconductor field-effect transistors, top) for integrated circuits (ring oscillator, mid) and system-level medical device (electrical nerve stimulator, bottom). Adapted with permission from References 1, 4, and 6. © 2012 AAAS, 2018 Springer Nature, and 2013 Wiley, respectively, (e) Representative application fields of transient electronics. Adapted with permission from References 2 and 9. © 2016 Springer Nature, 2018 Springer Nature, and 2015 Wiley, respectively. Note: PE-CVD, plasma-enhanced chemical vapor deposition; ALD, atomic layer deposition; PDPP-PD, poly(diketopyrrolopyrrole-p-phenylenediamine); TMSO, trimethylsilyl-o; TMSC, trimethylsilyl-cellulose; PLGA, poly(lactic-co-glycolic acid).
This issue of MRS Bulletin introduces recent developments and advances in transient electronics devices and is organized into five topics. The article by Choi et al. is the overall development of transient electronics using inorganic materials.23 The transient behavior and biocompatibility of key elements are discussed in comprehensive electrochemical terms, and a biomedical system is introduced as a representative example. The article by Liu et al. is the development of biodegradable organic materials for transient electronics.24 Soft and bio-friendly devices are available that use organic materials for flexible, stretchable applications. Biodegradable polymers are also widely highlighted as substrates and encapsulation layers that are essential for protection electronics. In their article in this issue, Han et al. discuss a fabrication technology that integrates reactive transient materials into devices.25 This method focuses on the integration of inorganic and organic transient materials to exploit their complementary electrical and mechanical properties. The article by Jia et al. introduces a transient energy source as a representative example of a fully formed device.26 The materials, structure, and electronic device design for energy-storage technology are reviewed, including energy-storage devices such as batteries and capacitors, and energy-harvesting technologies such as piezoelectricity, tribogenerators, photovoltaics, and wireless power-transmission technologies. The final article by You et al.27 discusses on-demand control of transient device lifetimes, so-called trigger-transient electronics. Strategies to remove materials via various stimuli such as light and heat as well as solution reactions are reviewed. In the sections that follow, we provide a brief overview of each of these topics as presented in the articles in this issue.
Biodegradable inorganic materials for transient electronics
Inorganic transient electronics that exploit the excellent electrical properties and stability of inorganic materials have expanded rapidly after the initial demonstration of the dissolution of electrical-grade single-crystal Si nanomembranes. Hwang et al. showed that ~100-nm-thick single-crystal Si dissolved in a phosphate buffer solution at 37°C at a rate of ~3 nm/day, suggesting the potential use of Si as transient or biodegradable electrical functional materials.1 The versatile electrical properties of Si provide various types of transient electronics, including electronic components such as transistors, diodes, and inductors, logic circuits, and optical, temperature, and strain sensors.1 The study of dissolution chemistry and kinetics of potential transient electronic materials has naturally become important. Follow-up studies demonstrate that Ge, SiGe, and amorphous indium gallium zinc oxide (a-IGZO) are also dissoluble in a phosphate buffer solution and can be alternative semiconductor layers.20,28 Dissolution kinetics strongly depend on materials microstructure such as density of films and crystallinity, and on environmental conditions such as temperature, pH, and ion species.1,17–19 The study of dissolution kinetics provides a tunable design factor for transient electronics by controlling the transient dissolution rate of individual components and overall systems.
Transient dielectrics play an additional important role as encapsulation materials that determine the life cycle of electronics. Transient electronics lose their electrical function when the electrically functional materials dissolve. Transient encapsulation slows down water diffusion toward the active circuit and extends the valid functional lifetime of the overall device. Representative metal or semiconductor oxides and nitrides such as MgO, SiO2, and SiNx have been introduced as transient dielectric materials.17 The key challenge in inorganic encapsulation is to minimize the defects that can cause water leakage. Several possible methods have been introduced using multiple layers, atomic-layer-deposited layers, and single-crystal Si nanomembranes for encapsulation.17,19
Silicon transient electronics are used in biodegradable medical sensing and treatment as minimally invasive implants based on the biocompatibility of Si where SiOH4, a byproduct of Si dissolution, is naturally present in the human body and usually evacuated through urine.29 Eliminating the necessity of secondary surgery greatly reduces the risks of surgery as well as the difficulties caused by permanent electronic implants. A recent demonstration showed comparable performance of biodegradable sensors in monitoring brain pressure or EEG and ECoG for diagnosis of symptoms with incubation periods such as traumatic brain injury2,3 Biodegradable devices are now available for biomedical actuation using wireless electrical stimulators to enhance or promote biological activity and regeneration.4
The article by Choi et al. overviews the dissolution chemistry of inorganic transient materials in biofluids, focusing on their kinetic behavior and biomedical applications.23
Biodegradable and flexible organic electronic materials
Biodegradable organic materials are useful as electrical functional layers—a semiconductor, conductor, and dielectric, a substrate to support the electrical circuit, and an encapsulation to protect the device. Organic materials offer tunability in electrical, mechanical, and biodegradable properties through modification of functional groups and blending of functional chains; and large-scale, low-cost production is available employing solution processes. Organic materials are suitable for flexible and stretchable devices that require wide deformation and conformai contact because of their soft and flexible mechanical properties relative to inorganic materials. The development of biodegradable electronic organic materials offers a chance to build a wide range of biocompatible flexible and stretchable devices with transient capabilities.
One of the first demonstrations of a transient organic thin-film transistor (OTFT) used fully biodegradable 5,5′-bis(7-dodecyll9H-fluoren-2-yl)-2,2′-bithiophene (DDFTTF) semiconductor, poly(vinyl alcohol) (PVA) dielectric and PLGA.13 The mobility reached 0.253 cm2/Vs and the ON/OFF ratio was 9.4 × 103 with PVA as the dielectric. A 10 mm × 10 mm × 2 mm OTFT was fully degraded in 70 days in a citrate buffer (pH 4.0) at 37°C.13
Many researchers have tried to adopt eco-friendly and biodegradable natural molecules to exploit their biocompatible features.14 A representative example is indigo, which has semiconducting properties due to strong hydrogen bonding and intramolecular π interaction. Indigo is degraded not only by water, but also by enzymes, bacteria, light, and oxidizing agents.14 Other naturally obtained molecules have been suggested for biodegradable electronics—semiconductors, including eumelanin, β-carotene, indanthrene yellow G, indanthrene brilliant orange RF, and perylene diimide; and dielectrics, including sugars (glucose, lactose, and sucrose), nucleobases (adenine and guanine), and caffeine.14
Efforts have recently been made to improve mobility by synthesizing biodegradable conjugated polymers and implementing them in organic electronic devices. Although synthesizing bonds capable of both conjugation and decomposition is highly challenging, imine bonds provide both biodegradability and biocompatibility. Pioneering work in this field15 was the synthesis of poly(diketopyrrolopyrrole-p-phenylenediamine) (PDPP-PD) for a demonstrated electronic device. PDPP-PD was synthesized by a condensation reaction of diketopyrrolopyrrole-aldehyde (DPP-CHO) and p-phenylenediamine with p-toluenesulfonic acid catalyst.15 A TFT with mobility of 0.21 ± 0.03 cm2/Vs was demonstrated using PDPP-PD (molecular weight Mr = 39.6 kDa), Al2O3, cellulose (800 nm, 2 g/m2) and Au as the active layer, dielectric layer, substrate, and electrode, respectively.15 The device provided conformai contact to human brain models and an avocado with a rough surface because of its flexibility and softness.
The article by Liu et al. surveys biodegradable organic electronic materials, from natural organics to synthetic polymers, and their application and performance in electronic devices.24
Fabrication strategies for transient electronics
Traditional semiconductor fabrication processes require high temperatures and reactive solvents, and thus have limited applicability to typical biodegradable materials due to their low thermostability and high chemical reactivity. Moreover, strategies are needed to fabricate hybrid layers of organic-inorganic materials so as to utilize both the outstanding electrical performance of inorganic materials and the mechanical flexibility of organic ones. Representative methods for the fabrication of transient electronics include (1) transfer-printing processes that separate reactive-sensitive materials from the electronic fabrication and integrate them after printing, and (2) solution processes that print composites of inorganic functional particles in an organic matrix.
In one of the first demonstrations of inorganic transient electronics, transient devices were fabricated by physical vapor deposition of dielectric layers (MgO or SiO2) and electrode layers (Mg) using stencil masks on a substrate (silk), combined with transfer printing of silicon nanomembranes from silicon-on-insulator (SOI) wafers.1 This procedure involves no thermal and chemical processes to damage biodegradable organic substrates such as silk and PLGA because most of the inorganic layer is formed by physical deposition and transfer printing.
Hwang et al. demonstrated the mass transfer of MOSFETs using anisotropic etching of SOI wafers with Si(111) handles, which provide the full wafer process without limitations on thermal processing and feature size.16 The MOSFETs consisted of Si nanomembranes (~100 nm) for the active channel, SiO2 (~100 nm) for the gate dielectric, and Mg (~200 nm) for contact metals formed by 950~1050°C doping, 250°C plasma-enhanced chemical vapor deposition (PECVD), and electron-beam evaporation deposition, respectively. Selective etching using reactive ion etching (RIE) formed the trench to allow the anisotropic undercut of the Si(111) handle toward the (110) direction using tetramethylammonium hydroxide (TMAH) to release the preformed MOSFETs from the SOI wafer. Undercut MOSFETs could be individually transferred by PDMS stamps on biodegradable polymers such as PLGA.
This type of modified Si fabrication processing and transfer-printing technique offers potential mass production of biodegradable Si transient devices through foundry facilities.22 High- and uniform-performance components (e.g., diodes and MOSFETs) with well-defined processing conditions can be produced in bulk on 6-in. Si(111) wafers. SiO2 (dielectric), SiNx (passivation), W (metal interconnect), and Ti/TiN (adhesion layer) were chosen for adaptation to the foundry process. The device, separated by selective etching using TMAH or KOH using a SOI (111) transfer method, could be transferred onto a biodegradable polymer (PLGA).22 This suggests the possibility of using transient electronics as chip units capable of performing complex calculation or logic functions, including integrated circuit levels beyond laboratory-scale demonstration.
Solution process-based printing of inorganic-organic hybrid composites are also available for transient electronics and have the advantages of low temperature, low cost, and simple processing. Huang et al. developed conductive organic-inorganic composites with in-plane conductivity of ~3500 S/m (W) and 0.024 S/m (Zn) by blending W or Zn microparticles (4 ~12 urn) with poly(ethylene oxide) (PEO).30 Conductive composites formed by screen printing can be used as inductive coils for wireless communication as well as circuit electrodes. Lee et al. have reported conductive composites that maintain conductivity in 37°C deionized water for nine days by blending Mo microparticles (1~5 µm) and hydrophobic polybutanedithiol 1,3,5-triallyl-l,3,5-triazine-2,4,6(1H,3H,5H)-trione pentenoic anhydride) (PBTPA).31 The electrical properties and dissolution behavior of inorganic-organic blend mixtures can be controlled by particle size, concentration, and the polymer matrix.
The article by Han et al. details fabrication strategies to integrate high-performance inorganic transient materials and soft organic substrates. It also describes recent developments in electronic printing using transient composites.25
Transient energy devices
The development of transient energy sources is essential to supply power to transient devices. There are two main streams of energy supply: (1) energy storage using batteries and capacitors, and (2) energy harvesting from the environment using materials such as piezoelectrics, photovoltaics, and triboelectrics.1,32–34 It is challenging to design transient energy sources due to the few materials available, although the lifespan required is shorter than those in conventional usage. The primary goal of current research in transient energy devices is to design combinations of materials and structures that can deliver sustainable power to achieve desirable operational characteristics.
A battery is a good energy source due to its high energy density and stable energy supply. Figure 2a shows a galvanic cell that uses biodegradable metal electrodes (Mg for the anode, Fe, W, Mo for the cathode), phosphate buffer saline (PBS) electrolyte, and polyanhydride packaging.32 Single-cell batteries composed of Mg-X metal foil (X = Fe, W, or Mo) under a constant discharge current density (0.1 mA/cm2) can stably produce voltages of ~0.75 V, ~0.65 V, ~0.45 V for Mg-Fe, Mg-W, and Mg-Mo, respectively. Series stacking of single cells can enhance the output voltage; for example, four stacks of Mg-Mo generate 1.5~1.6 V under a constant-discharge current density condition (0.1 mA/cm2). Modulating the combinations of electrode materials, electrolyte and coating materials, and anode thickness offers tunability in current density, output voltage, and lifespan.
Schematics of transient energy devices, (a) Battery with four stacking Mg-Mo cells in series. Adapted with permission from Reference 27. © 2014 Wiley, (b) Mechanical energy harvester using triboelectricity. Scale bar =10 urn. Adapted with permission from Reference 29. © 2016 AAAS. (c) Wireless energy transfer with near-field inductive coupling. Adapted with permission from Reference 2. © 2016 Springer Nature. Note: PLGA, poly(lactic-co-glycolic acid); NFC, near-field communication; BDP, biodegradable polymer.
Energy harvesters that convert physical energy into electrical energy can also be used as transient energy sources. Figure 2b shows several examples of transient energy harvesters. A representative energy harvester has been suggested using biodegradable and piezoelectric metal oxide, ZnO with biodegradable Mg electrode, and silk substrates.33 As a mechanical energy harvester, this device generates ~0.55 nA current, ~1.14V output voltage, and ~10 nW/cm2 power density with 0.28% energy-conversion efficiency. A recent study explored another type of mechanical energy harvester, a triboelectric generator: the friction between two different biodegradable polymers such as PLGA, PVA, PCL, and PHB/V can generate a power of 32.6 mW/m2.34
Device size, life span, and energy densities remain key issues in batteries and various energy harvesters for biodegradable applications where miniaturization, long-term operation, and sufficient power are critical. Wireless transmitting power using near-field inductive coupling has been proposed as an alternative to implantable transient devices. The effectiveness of this type of energy transfer has been verified by recent biomedical applications in wireless hyperthermia to minimize residual bacteria after surgery, electrical stimulation to accelerate peripheral nerve regeneration, and heat modulation to control drug delivery.2,3,5 Figure 2c shows wireless power and data transmitting devices using inductive coupling for wireless monitoring of intracranial pressure.2
The article by Jia et al. summarizes transient energy sources, focusing especially on energy-storage devices from batteries to supercapacitors.26
Triggered transient electronics for active lifetime control
The lifetimes of most eco-/bioresorbable or water-soluble forms of transient electronics are, as previously described, passively determined by the selection of constituent materials and system geometries, where ambient conditions (e.g., pH, temperature, and ionic content of the surrounding aqueous environments) dictate the overall dissolution kinetics. Advanced approaches, sometimes referred to as triggered transience,7–10 make possible deterministic, active control over the initiation of dissolution, disintegration, depolymerization, or other chemical or physical processes. Such capabilities can be exploited in biomedical devices to allow the release of drugs at specific intervals or in military systems to enable destruction of secured hardware upon recovery by an adversary. Several studies illustrate on-demand, fast, and accurate control over the behavior of transient electronics with diverse materials systems, device structures, and trigger stimuli.
Figure 3a shows an example of triggering in which disintegration of a supporting substrate of cyclic poly(phthalaldehyde) (cPPA) occurs upon exposure to light.7 Here, the cPPA contains 2.5–5% of 2-(4-methoxystyryl)-4,6-bis(trichloromethyl)-1,3,5-triazine (MBTT) as a dopant that yields photoactivated reactive Cl• radical species and hydrochloric acid (HCl), to cleave the acetal backbone of the cPPA. Exposure to UV light (λmax = 365 nm) initiates depolymerization of the cPPA, leading to the disintegration of the ultrathin electronic components on the substrate.
Triggered transient electronics for active lifetime control, (a) Photoinitiated transiency of 2-(4-methoxystyryl)-4,6-bis(trichloromethyl)-1,3,5-triazine (MBTT)/cyclic poly(phthalaldehyde) (cPPA) substrate with electronics. Adapted with permission from Reference 7. © 2014 Wiley, (b) Transiency of acid-sensitive substrates (cPPA) and circuit (Mg) by release of methanesulfonic acid dispersed in wax encapsulation initiated by heat melting. Adapted with permission from Reference 9. © 2015 Wiley, (c) Structure of mechanical destruction of electronics by using an expandable polymer. Adapted with permission from Reference 8. © 2017 Wiley, (d) Wireless microfluidic device with thermal expansion polymer, and series of images showing the selective and sequential injection of water with dye by heat triggering the expandable polymer. Adapted with permission from Reference 10. ©2014 Wiley.
Thermal triggering mechanisms provide a complementary set of opportunities. In one example, metastable substrates such as cyclododecane (C12H24) sublime under ambient conditions; this accelerates at elevated temperatures to induce disintegration of the supported electronics.35 Figure 3b shows further examples of triggering by thermal means, where advanced chemistries allow additional flexibility.9 Park et al. describe a wax with 3% methanesulfonic acid introduced by stirring at 70°C; upon melting, rapid degradation of acid-sensitive metal interconnect lines (i.e., Mg) and substrate (i.e., cPPA) occurs by chemical etching.9 A radio-frequency approach allows wireless delivery of thermal power for remote triggering.
Other strategies rely on the thermal expansion of polymers to fracture the essential components of electrical circuits8 or to cause the release of active liquid species from microfluidic reservoirs10 for chemical reactions or pharmacological delivery. As an example of the former, Figure 3c shows the instant destruction of a device on a thermally expandable polymer (Expancel 031 DU 40, AkzoNobel) composed of polymeric microspheres that encapsulate small amounts of liquid hydrocarbon.8 When an integrated thermal actuator reaches temperatures above 80°C, the polymer expands irreversibly by nearly 10 times due to a phase change of the hydrocarbon from liquid to gas. Figure 3d shows a microfluidic system that releases etchants upon heating of a polymer beyond a critical level.10 Water and sodium hydroxide act to dissolve Mg (Mg + 2H2O → Mg(OH)2 + H2) and Al (2A1 + 2NaOH + 2H2O → 2NaA102 + 3H) electrodes, respectively, thereby destroying an antenna by etching.
The article by You et al. surveys strategies in triggered transient electronics to initiate degradation or terminate device function on demand via various stimuli.27
Outlook
Transient electronics research has seen explosive recent expansion in the discovery and analysis of water-soluble or degradable materials, and demonstrations of versatile devices for applications. The potential of transient electronics and the possibility of translation to applications relevant and useful to society has been clearly demonstrated.
Moving forward, we believe that the following areas of materials research are necessary: (1) precise control of degradation and operational lifetime adjustment, (2) development of new classes of transient electronic materials to increase the choice of electronic and degradation properties and other functionality, and (3) evolution toward high-performance electronics to translate the techniques to industry.
Transient electronics require sophisticated efforts to reduce the gap between materials degradation and the functional lifetime of electronic devices. This gap arises from the quick diffusion of water molecules through the protective layer into the electronic circuit before the protective layer can dissolve out. Enhancing the water-barrier properties of encapsulation layers is critical for precise control of the functional lifetime without increased layer thickness or total degradation time. This requires understanding the dissolution kinetics of water-diffusion behavior and developing nano structural or molecular approaches to control it. The surface modification of transient encapsulation, one potential solution, requires understanding the surface chemistry at the molecular level to control the interaction between water molecules and the surface. Work on forming extremely dense encapsulation structures is also essential to slow down vapor diffusion into the layer. All of these considerations must be explored in transient passive materials, and the fields under consideration will no doubt expand.
The choice of electronic materials in transient electronics is limited to some inorganics and polymers whose dissolution chemistry and kinetics are known, especially at this new thickness scale. There are still great opportunities to discover new water-soluble or biodegradable electronic components that are electrically conductive and have semiconducting and dielectric properties. This effort can be furthered by exploring new classes of metal alloys with biodegradable components, designing nanostructured materials with transient metal and metal oxides, and synthesizing new types of polymers. Composites of transient inorganics and polymers are another great option. This will enrich the design choices for electronic devices by consideration of various electrical, transient, mechanical, and other properties.
In another direction, current techniques must be translated to industry so that they can influence medical practice. The first step will be moving forward to chip-scale devices made by reliable, high-performance processing. Most current demonstrations of transient electronics remain in the realm of materials development with one or two simple functional operations. Designing and developing chip-scale devices will be the first step toward the sophisticated transient devices with extensive performance and applications. Continuous efforts must be made to find materials and fabrication methods that are compatible with industrial processes. Extensive research in this translation stage should also explore the materials issues and reliability problems that will arise in stacking and packaging such chips
The articles in this issue not only summarize and overview recent developments in transient electronics in representative fields, they also offer information, suggestions, and ideas for the next generation of transient electronics devices.
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Kang, SK., Yin, L. & Bettinger, C. The emergence of transient electronic devices. MRS Bulletin 45, 87–95 (2020). https://doi.org/10.1557/mrs.2020.19
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DOI: https://doi.org/10.1557/mrs.2020.19