Saved in:
Bibliographic Details
Main Authors: Rocha, Denis, Lopes, Pedro, Peixoto, Paulo, de Almeida, Anibal, Tavakoli, Mahmoud
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.11016
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916572103180288
author Rocha, Denis
Lopes, Pedro
Peixoto, Paulo
de Almeida, Anibal
Tavakoli, Mahmoud
author_facet Rocha, Denis
Lopes, Pedro
Peixoto, Paulo
de Almeida, Anibal
Tavakoli, Mahmoud
contents Over the past years, rapid progress has been made on soft-matter electronics for wearable and implantable devices, for bioelectronics and optogenetics. Liquid Metal (LM) based electronics were especially popular, due to their long-term durability, when subject to repetitive strain cycles. However, one major limitation has been the need for tethering bioelectronics circuits to external power, or the use of rigid bulky batteries. This has motivated a growing interest in wireless energy transfer, which demands circuit miniaturization. However, miniaturization of LM circuits is challenging due to low LM-substrate adhesion, LM smearing, and challenges on microchip-interfacing. In this article, we address these challenges by high-resolution laser-assisted micropatterning of biphasic LM composites and vapor-assisted LM microchip soldering. Through development of a search algorithm for optimization of the biphasic ink coil performance, we designed and implemented micro coils with trace spacing of 50 μm that can harvest a significant amount of energy (178 mW/cm2) through near field inductive coupling. We show miniaturized soft-matter circuits with integrated SMD chips such as NFC chips, capacitors, and LEDs that are implemented in a few minutes through laser patterning, and vaporassisted soldering. In the context of optogenetics, where lightweight, miniaturized systems are needed to provide optical stimulation, soft coils stand out in terms of their improved conformability and flexibility. Thus, this article explores the applications of soft coils in wearable and implantable devices, with a specific focus on their use in optogenetics.
format Preprint
id arxiv_https___arxiv_org_abs_2501_11016
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Miniaturized liquid metal composite circuits with energy harvesting coils for battery-free bioelectronics and optogenetics
Rocha, Denis
Lopes, Pedro
Peixoto, Paulo
de Almeida, Anibal
Tavakoli, Mahmoud
Medical Physics
Biological Physics
Over the past years, rapid progress has been made on soft-matter electronics for wearable and implantable devices, for bioelectronics and optogenetics. Liquid Metal (LM) based electronics were especially popular, due to their long-term durability, when subject to repetitive strain cycles. However, one major limitation has been the need for tethering bioelectronics circuits to external power, or the use of rigid bulky batteries. This has motivated a growing interest in wireless energy transfer, which demands circuit miniaturization. However, miniaturization of LM circuits is challenging due to low LM-substrate adhesion, LM smearing, and challenges on microchip-interfacing. In this article, we address these challenges by high-resolution laser-assisted micropatterning of biphasic LM composites and vapor-assisted LM microchip soldering. Through development of a search algorithm for optimization of the biphasic ink coil performance, we designed and implemented micro coils with trace spacing of 50 μm that can harvest a significant amount of energy (178 mW/cm2) through near field inductive coupling. We show miniaturized soft-matter circuits with integrated SMD chips such as NFC chips, capacitors, and LEDs that are implemented in a few minutes through laser patterning, and vaporassisted soldering. In the context of optogenetics, where lightweight, miniaturized systems are needed to provide optical stimulation, soft coils stand out in terms of their improved conformability and flexibility. Thus, this article explores the applications of soft coils in wearable and implantable devices, with a specific focus on their use in optogenetics.
title Miniaturized liquid metal composite circuits with energy harvesting coils for battery-free bioelectronics and optogenetics
topic Medical Physics
Biological Physics
url https://arxiv.org/abs/2501.11016