Your search keyword '"Engquist, Isak"' showing total 20 results

1. Rationally designed conductive wood with mechanoresponsive electrical resistance

Author

Mastantuoni, Gabriella G., Tran, Van Chinh, Garemark, Jonas, Dreimol, Christopher H., Engquist, Isak, Berglund, Lars A., and Zhou, Qi

Published

2024

2. Ultrathin polymer electrochemical microcapacitors for on-chip and flexible electronics

Author

Say, Mehmet Girayhan, Donahue, Mary J., Kroon, Renee, Berggren, Magnus, and Engquist, Isak

Published

2023

3. Printable carbon-based supercapacitors reinforced with cellulose and conductive polymers

Author

Belaineh, Dagmawi, Brooke, Robert, Sani, Negar, Say, Mehmet Girayhan, Håkansson, Karl M.O., Engquist, Isak, Berggren, Magnus, and Edberg, Jesper

Published

2022

4. The effect of crosslinking on ion transport in nanocellulose-based membranes

Author

Yang, Hongli, Edberg, Jesper, Gueskine, Viktor, Vagin, Mikhail, Say, Mehmet Girayhan, Erlandsson, Johan, Wågberg, Lars, Engquist, Isak, and Berggren, Magnus

Published

2022

5. Stretchable and biodegradable plant-based redox-diffusion batteries.

Author

Rahmanudin, Aiman, Mohammadi, Mohsen, Isacsson, Patrik, Li, Yuyang, Seufert, Laura, Kim, Nara, Mardi, Saeed, Engquist, Isak, Crispin, Reverant, and Tybrandt, Klas

Published

2024

6. Digital Cellulose: Recent Advances in Electroactive Paper.

Author

Brooke, Robert, Jain, Karishma, Isacsson, Patrik, Fall, Andreas, Engquist, Isak, Beni, Valerio, Wågberg, Lars, Granberg, Hjalmar, Hass, Ursula, and Edberg, Jesper

Abstract

With the increasing global demand for net-zero carbon emissions, actions to address climate change have gained momentum among policymakers and the public. The urgent need for a sustainable economy is underscored by the mounting waste crisis in landfills and oceans. However, the proliferation of distributed electronic devices poses a significant challenge due to the resulting electronic waste. To combat this issue, the development of sustainable and environmentally friendly materials for these devices is imperative. Cellulose, an abundant and CO2-neutral substance with a long history of diverse applications, holds great potential. By integrating electrically interactive components with cellulosic materials, innovative biobased composites have been created, enabling the fabrication of bulk electroactive paper and the establishment of new, potentially more sustainable manufacturing processes for electronic devices. This review explores recent advances in bulk electroactive paper, including the fundamental interactions between its constituents, manufacturing techniques, and large-scale applications in the field of electronics. Furthermore, it addresses the importance and challenges of scaling up production of electroactive paper, highlighting the need for further research and development. [ABSTRACT FROM AUTHOR]

Published

2024

7. Study on the Rectification of Ionic Diode Based on Cross-Linked Nanocellulose Bipolar Membranes.

Author

Yang, Hongli, Edberg, Jesper, Say, Mehmet Girayhan, Erlandsson, Johan, Gueskine, Viktor, Wågberg, Lars, Berggren, Magnus, and Engquist, Isak

Published

2024

8. Direct Ink Writing of Nanocellulose and PEDOT:PSS for Flexible Electronic Patterned and Supercapacitor Papers.

Author

Lay, Makara, Say, Mehmet Girayhan, and Engquist, Isak

Subjects

ELECTRONIC paper, CARBON nanofibers, ORGANIC electronics, FLEXIBLE electronics, CLEAN energy, ELECTRIC currents, SUPERCAPACITORS

Abstract

Printed electronic paper identifies its interest in flexible organic electronics and sustainable and clean energy applications because of its straightforward production method, cost‐effectiveness, and positive environmental impact. However, current limitations include restricted material thickness and the use of supporting substrate for printing. Here, 2D and 3D electronic patterned paper are fabricated from direct ink writing (DIW) nanocellulose and PEDOT:PSS‐based materials using syringe deposition and 3D printing. The conductor patterns are integrated in the bulk of the paper, while non‐conductive sections are used as support to form free‐standing paper. The strong interface between the patterns of electronic patterned paper gives mechanical stability for practical handling. The conductive paper‐based electrode has 202 S cm−1 and is capable of handling electric current up to 0.7 A, which can be used for high‐power devices. Printed supercapacitor papers show high specific energy of 4.05 Wh kg−1, specific power of 4615 W kg−1 at 0.06 A g−1, and capacitance retention above 95% after 2000 cycles. The new design structure of electronic patterned papers presents a solution for additive manufacturing of paper‐based composites for supercapacitors, wearable electronics, or sensors for smart packaging. [ABSTRACT FROM AUTHOR]

Published

2023

9. Toward Photoactive Wallpapers Based on ZnO‐Cellulose Nanocomposites.

Author

Alvi, Naveed Ul Hassan, Sepat, Neha, Sardar, Samim, Berggren, Magnus, Engquist, Isak, and Crispin, Xavier

Subjects

CELLULOSE fibers, MANUFACTURING processes, WALLPAPER, NANOCOMPOSITE materials, COMPOSITE materials, CELLULOSE

Abstract

The quest for eco‐friendly materials with anticipated positive impact for sustainability is crucial to achieve the UN sustainable development goals. Classical strategies of composite materials can be applied on novel nanomaterials and green materials. Besides the actual technology and applications also processing and manufacturing methods should be further advanced to make entire technology concepts sustainable. Here, they show an efficient way to combine two low‐cost materials, cellulose and zinc oxide (ZnO), to achieve novel functional and "green" materials via paper‐making processes. While cellulose is the most abundant and cost‐effective organic material extractable from nature. ZnO is cheap and known of its photocatalytic, antibacterial, and UV absorption properties. ZnO nanowires are grown directly onto cellulose fibers in water solutions and then dewatered in a process mimicking existing steps of large‐scale papermaking technology. The ZnO NW paper exhibits excellent photo‐conducting properties under simulated sunlight with good ON/OFF switching and long‐term stability (90 minutes). It also acts as an efficient photocatalyst for hydrogen peroxide (H2O2) generation (5.7 × 10−9 m s−1) with an envision the possibility of using it in buildings to enable large surfaces to spontaneously produce H2O2 at its outer surface. Such technology promise for fast degradation of microorganisms to suppress the spreading of diseases. [ABSTRACT FROM AUTHOR]

Published

2023

10. Electrical current modulation in wood electrochemical transistor.

Author

Van Chinh Tran, Mastantuoni, Gabriella G., Zabihipour, Marzieh, Lengwan Li, Berglund, Lars, Berggren, Magnus, Qi Zhou, and Engquist, Isak

Subjects

WOOD, TRANSISTORS, ELECTRIC conductivity, ELECTRONIC equipment, CONDUCTING polymers

Abstract

The nature of mass transport in plants has recently inspired the development of low-cost and sustainable wood-based electronics. Herein, we report a wood electrochemical transistor (WECT) where all three electrodes are fully made of conductive wood (CW). The CW is prepared using a two-step strategy of wood delignification followed by wood amalgamation with a mixed electron-ion conducting polymer, poly(3,4-ethylenedioxythiophene)-polystyrene sulfonate (PEDOT:PSS). The modified wood has an electrical conductivity of up to 69 Sm-1 induced by the formation of PEDOT:PSS microstructures inside the wood 3D scaffold. CW is then used to fabricate the WECT, which is capable of modulating an electrical current in a porous and thick transistor channel (1 mm) with an on/off ratio of 50. The device shows a good response to gate voltage modulation and exhibits dynamic switching properties similar to those of an organic electrochemical transistor. This wood-based device and the proposed working principle demonstrate the possibility to incorporate active electronic functionality into the wood, suggesting different types of bio-based electronic devices. [ABSTRACT FROM AUTHOR]

Published

2023

11. Nanocellulose and PEDOT:PSS composites and their applications.

Author

Brooke, Robert, Lay, Makara, Jain, Karishma, Francon, Hugo, Say, Mehmet Girayhan, Belaineh, Dagmawi, Wang, Xin, Håkansson, Karl M. O., Wågberg, Lars, Engquist, Isak, Edberg, Jesper, and Berggren, Magnus

Subjects

ELECTROACTIVE substances, BIODEGRADABLE materials, CONDUCTIVE ink, MOLECULAR interactions, ENERGY harvesting, CONDUCTING polymers

Abstract

The need for achieving sustainable technologies has encouraged research on renewable and biodegradable materials for novel products that are clean, green, and environmentally friendly. Nanocellulose (NC) has many attractive properties such as high mechanical strength and flexibility, large specific surface area, in addition to possessing good wet stability and resistance to tough chemical environments. NC has also been shown to easily integrate with other materials to form composites. By combining it with conductive and electroactive materials, many of the advantageous properties of NC can be transferred to the resulting composites. Conductive polymers, in particular poly(3,4-ethylenedioxythiophene:poly(styrene sulfonate) (PEDOT:PSS), have been successfully combined with cellulose derivatives where suspensions of NC particles and colloids of PEDOT:PSS are made to interact at a molecular level. Alternatively, different polymerization techniques have been used to coat the cellulose fibrils. When processed in liquid form, the resulting mixture can be used as a conductive ink. This review outlines the preparation of NC/PEDOT:PSS composites and their fabrication in the form of electronic nanopapers, filaments, and conductive aerogels. We also discuss the molecular interaction between NC and PEDOT:PSS and the factors that affect the bonding properties. Finally, we address their potential applications in energy storage and harvesting, sensors, actuators, and bioelectronics. [ABSTRACT FROM AUTHOR]

Published

2023

12. In Situ Lignin Sulfonation for Highly Conductive Wood/Polypyrrole Porous Composites.

Author

Mastantuoni, Gabriella G., Tran, Van Chinh, Engquist, Isak, Berglund, Lars A., and Zhou, Qi

Subjects

WOOD, CONDUCTING polymer composites, POLYPYRROLE, LIGNINS, SULFONATION, ELECTRONIC equipment, WEIGHT gain

Abstract

To address the rising need of sustainable solutions in electronic devices, the development of electronically conductive composites based on lightweight but mechanically strong wood structures is highly desirable. Here, a facile approach for the fabrication of highly conductive wood/polypyrrole composites through top‐down modification of native lignin followed by polymerization of pyrrole in wood cell wall. By sodium sulfite treatment under neutral condition, sulfonated wood veneers with increased porosity but well‐preserved cell wall structure containing native lignin and lignosulfonates are obtained. The wood structure has a content of sulfonic groups up to 343 µmol g−1 owing to in situ sulfonated lignin which facilitates subsequent oxidative polymerization of pyrrole, achieving a weight gain of polypyrrole as high as 35 wt%. The lignosulfonates in the wood structure act as dopant and stabilizer for the synthesized polypyrrole. The composite reaches a high conductivity of 186 S m−1 and a specific pseudocapacitance of 1.71 F cm−2 at the current density of 8.0 mA cm−2. These results indicate that tailoring the wood/polymer interface in the cell wall and activating the redox activity of native lignin by sulfonation are important strategies for the fabrication of porous and lightweight wood/conductive polymer composites with potential for sustainable energy applications. [ABSTRACT FROM AUTHOR]

Published

2023

13. Cross-Linked Nanocellulose Membranes for Nanofluidic Osmotic Energy Harvesting.

Author

Yang, Hongli, Gueskine, Viktor, Berggren, Magnus, and Engquist, Isak

Published

2022

14. Scalable Paper Supercapacitors for Printed Wearable Electronics.

Author

Say, Mehmet Girayhan, Brett, Calvin J., Edberg, Jesper, Roth, Stephan V., Söderberg, L. Daniel, Engquist, Isak, and Berggren, Magnus

Published

2022

15. Production of energy-storage paper electrodes using a pilot-scale paper machine.

Author

Isacsson, Patrik, Jain, Karishma, Fall, Andreas, Chauve, Valerie, Hajian, Alireza, Granberg, Hjalmar, Boiron, Lucie, Berggren, Magnus, Håkansson, Karl, Edberg, Jesper, Engquist, Isak, and Wågberg, Lars

Abstract

The global efforts in electrifying our society drive the demand for low-cost and sustainable energy storage solutions. In the present work, a novel material concept was investigated to enable fabrication of several 10 meter-long rolls of supercapacitor paper electrodes on a pilot-scale paper machine. The material concept was based on cationized, cellulose-rich wood-derived fibres, conducting polymer PEDOT:PSS, and activated carbon filler particles. Cationic fibres saturated with anionic PEDOT:PSS provide a conducting scaffold hosting the activated carbon, which functions as the active charge-storage material. The response from further additives was systematically investigated for several critical paper properties. Cellulose nanofibrils were found to improve mechanical properties, while carbon black enhanced both the conductivity and the storage capacity of the activated carbon, reaching a specific capacitance of 67 F g−1. This pilot trial shows that "classical" papermaking methods are fit for the purpose and provides valuable insights on how to further advance bio-based energy storage solutions for large-scale applications. [ABSTRACT FROM AUTHOR]

Published

2022

16. Upscalable ultra thick rayon carbon felt based hybrid organic‐inorganic electrodes for high energy density supercapacitors.

Author

Wang, Xin, Say, Mehmet Girayhan, Brooke, Robert, Beni, Valerio, Nilsson, David, Lassnig, Roman, Berggren, Magnus, Edberg, Jesper, and Engquist, Isak

Subjects

ENERGY density, RAYON, ENERGY storage, SUPERCAPACITOR electrodes, SUPERCAPACITORS, POWER density, ELECTRODES

Abstract

Low weight, small footprint, and high performances are essential requisites for the implementation of energy storage devices within consumer electronics. One way to achieve these goals is to increase the thickness of the active material layer. In this work, carbonized and graphitized rayon felt, a cellulose‐derived material, is used as a three‐dimensional current collector scaffold to enable the incorporation of large amount of active energy storage materials and ionic liquid‐based gel electrolyte in the supercapacitor devices. PEDOT:PSS, alone or in combination with active carbon, has been used as the active material. Three‐dimensional supercapacitors with high per unit area capacitance (more than 1.1 F/cm2) have been achieved owing to the loading of large amount of active material in the felt matrix. Areal energy density of more than 101 μWh/cm2 and areal power density of more than 5.9 mW/cm2 have been achieved for 0.8 V operating voltage at a current density of 1 mA/cm2. A nanographite material was found to be beneficial in reducing the internal serial resistance of the supercapacitor to lower than 1.7 Ω. Furthermore, it was shown that even after 2000 times cycling test, the devices could still retain its performance with at least 88% coulombic efficiency for all the devices. All the materials are readily available commercially, environmentally sustainable and the process can potentially be upscaled with industrial process. [ABSTRACT FROM AUTHOR]

Published

2022

17. High‐Gain Logic Inverters based on Multiple Screen‐Printed Organic Electrochemical Transistors.

Author

Zabihipour, Marzieh, Tu, Deyu, Forchheimer, Robert, Strandberg, Jan, Berggren, Magnus, Engquist, Isak, and Andersson Ersman, Peter

Subjects

COMPUTER logic, ORGANIC field-effect transistors, VARISTORS, LOGIC circuits, HIGH voltages, ANALOG circuits, TRANSISTORS

Abstract

Organic electronic circuits based on organic electrochemical transistors (OECTs) are attracting great attention due to their printability, flexibility, and low voltage operation. Inverters are the building blocks of digital logic circuits (e.g., NAND gates) and analog circuits (e.g., amplifiers). However, utilizing OECTs in electronic logic circuits is challenging due to the resulting low voltage gain and low output voltage levels. Hence, inverters capable of operating at relatively low supply voltages, yet offering high voltage gain and larger output voltage windows than the respective input voltage window are desired. Herein, inverters realized from poly(3,4‐ethylenedioxythiophene):polystyrene sulfonate‐based OECTs are designed and explored, resulting in logic inverters exhibiting high voltage gains, enlarged output voltage windows, and tunable switching points. The inverter designs are based on multiple screen‐printed OECTs and a resistor ladder, where one OECT is the driving transistor while one or two additional OECTs are used as variable resistors in the resistor ladder. The inverters' performances are investigated in terms of voltage gain, output voltage levels, and switching point. Inverters, operating at +/−2.5 V supply voltage and an input voltage window of 1 V, that can achieve an output voltage window with ∼110% increment and a voltage gain up to 42 are demonstrated. [ABSTRACT FROM AUTHOR]

Published

2022

18. Utilizing native lignin as redox-active material in conductive wood for electronic and energy storage applications.

Author

Tran, Van Chinh, Mastantuoni, Gabriella G., Belaineh, Dagmawi, Aminzadeh, Selda, Berglund, Lars A., Berggren, Magnus, Zhou, Qi, and Engquist, Isak

Abstract

Nanostructured wood veneer with added electroactive functionality combines structural and functional properties into eco-friendly, low-cost nanocomposites for electronics and energy technologies. Here, we report novel conducting polymer-impregnated wood veneer electrodes where the native lignin is preserved, but functionalized for redox activity and used as an active component. The resulting electrodes display a well-preserved structure, redox activity, and high conductivity. Wood samples were sodium sulfite-treated under neutral conditions at 165 °C, followed by the tailored distribution of PEDOT:PSS, not previously used for this purpose. The mild sulfite process introduces sulfonic acid groups inside the nanostructured cell wall, facilitating electrostatic interaction on a molecular level between the residual lignin and PEDOT. The electrodes exhibit a conductivity of up to 203 S m−1 and a specific pseudo-capacitance of up to 38 mF cm−2, with a capacitive contribution from PEDOT:PSS and a faradaic component originating from lignin. We also demonstrate an asymmetric wood pseudo-capacitor reaching a specific capacitance of 22.9 mF cm−2 at 1.2 mA cm−2 current density. This new wood composite design and preparation scheme will support the development of wood-based materials for use in electronics and energy storage. [ABSTRACT FROM AUTHOR]

Published

2022

19. Ultrathin Paper Microsupercapacitors for Electronic Skin Applications.

Author

Say, Mehmet Girayhan, Sahalianov, Ihor, Brooke, Robert, Migliaccio, Ludovico, Głowacki, Eric D., Berggren, Magnus, Donahue, Mary J., and Engquist, Isak

Subjects

ELECTRONIC paper, ELECTROCHROMIC devices, FINITE element method, ENERGY storage, WEARABLE technology, SUPERCAPACITOR electrodes

Abstract

Ultrathin devices are rapidly developing for skin‐compatible medical applications and wearable electronics. Powering skin‐interfaced electronics requires thin and lightweight energy storage devices, where solution‐processing enables scalable fabrication. To attain such devices, a sequential deposition is employed to achieve all spray‐coated symmetric microsupercapacitors (μSCs) on ultrathin parylene C substrates, where both electrode and gel electrolyte are based on the cheap and abundant biopolymer, cellulose. The optimized spraying procedure allows an overall device thickness of ≈11 µm to be obtained with a 40% active material volume fraction and a resulting volumetric capacitance of 7 F cm−3. Long‐term operation capability (90% of capacitance retention after 104 cycles) and mechanical robustness are achieved (1000 cycles, capacitance retention of 98%) under extreme bending (rolling) conditions. Finite element analysis is utilized to simulate stresses and strains in real‐sized μSCs under different bending conditions. Moreover, an organic electrochromic display is printed and powered with two serially connected μ‐SCs as an example of a wearable, skin‐integrated, fully organic electronic application. [ABSTRACT FROM AUTHOR]

Published

2022

20. Designing Inverters Based on Screen Printed Organic Electrochemical Transistors Targeting Low‐Voltage and High‐Frequency Operation.

Author

Zabihipour, Marzieh, Tu, Deyu, Strandberg, Jan, Berggren, Magnus, Engquist, Isak, and Andersson Ersman, Peter

Subjects

SCREEN process printing, ELECTRONIC circuits, TRAFFIC safety, INTERNET of things, TRANSISTORS, POWER electronics, ORGANIC electronics, ORGANIC field-effect transistors

Abstract

Low‐voltage operating organic electronic circuits with long‐term stability characteristics are receiving increasing attention because of the growing demands for power efficient electronics in Internet of Things applications. To realize such circuits, inverters, the fundamental constituents of many circuits, with stable transfer characteristics should be designed to provide low‐power consumption. Here, a rational inverter design, based on fully screen printed p‐type organic electrochemical transistors with a channel size of 150 × 80 µm2, is explored for driving conditions with input voltage levels that differs of about 1 V. Further, three different inverter circuits are explored, including resistor ladders with resistor values ranging from tens of kΩ to a few MΩ. The performance of single inverters, 3‐stage cascaded inverters and 3‐stage ring oscillators are characterized with respect to output voltage levels, propagation delay, static power consumption, voltage gain, and operational frequency window. Depending on the application, the key performance parameters of the inverter can be optimized by the specific combination of the input voltage levels and the resistor ladder values. A few of the inverters are in fact fully functional up to 30 Hz, even when using input voltage levels as low as (0 V, 1 V). [ABSTRACT FROM AUTHOR]

Published

2021