Theoretical analysis of magneto-inductive THZ wireless communications and power transfer with multi-layer graphene nano-coils

Name: Theoretical analysis of magneto-inductive THZ wireless communications and power transfer with multi-layer graphene nano-coils
Author: Gülbahar, Burhan

İsim	Theoretical analysis of magneto-inductive THZ wireless communications and power transfer with multi-layer graphene nano-coils
Yazar	Gülbahar, Burhan
Basım Tarihi:	2017-03
Basım Yeri	- IEEE
Konu	Graphene, In-body, Magnetoinductive communications, Nanoscale, On-chip, Power transfer, THz
Tür	Süreli Yayın
Dil	İngilizce
Dijital	Evet
Yazma	Hayır
Kütüphane:	Özyeğin Üniversitesi
Demirbaş Numarası	2332-7804
Kayıt Numarası	f15dc053-375d-4e74-984f-731f43c6f8e5
Lokasyon	Electrical & Electronics Engineering
Tarih	2017-03
Örnek Metin	Graphene with significant potentials in diverse areas of physical and biological sciences is proposed as a solution to complementary problems of semiconductor and biomedical industries, i.e., the on-chip (OC) interconnect bottleneck and in-body (IB) wireless communications/power transfer (PT), respectively. Emerging nanoscale solutions with radio frequency, optical, ultrasonic, or molecular channels in OC and IB media have various challenges including achievable footprints and frequency, energy consumption, medium dependent features, and interference. In this paper, major challenges are addressed with magneto-inductive (MI) transceivers by combining the advantages of THz operation frequency, unique features of intercalated multi-layer graphene (MLG) coils and range extension with MI waveguides. Our design promises scalable and high performance solutions for the OC interconnect bottleneck while providing biocompatible and universal solutions for challenging IB medium. The proposed solution is theoretically analyzed and numerically compared with the copper-based alternatives, and the practical challenges are discussed. Simulation results achieve high capacity (several Tbit/s) and ultra-low power (500 zJ/bit) wireless communications while providing high (hundreds of kWs) and efficient (109 W/mm2) wireless PT at several millimeters. In addition, unique properties of MLG such as lightweight structure, biocompatibility, current carrying capacity, and planar manufacturability make the solution more promising for challenging environments.
DOI	10.1109/TMBMC.2017.2655022
Cilt	3

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Theoretical analysis of magneto-inductive THZ wireless communications and power transfer with multi-layer graphene nano-coils

Yazar Gülbahar, Burhan

Basım Tarihi 2017-03

Basım Yeri - IEEE

Konu Graphene, In-body, Magnetoinductive communications, Nanoscale, On-chip, Power transfer, THz

Tür Süreli Yayın

Dil İngilizce

Dijital Evet

Yazma Hayır

Kütüphane Özyeğin Üniversitesi

Demirbaş Numarası 2332-7804

Kayıt Numarası f15dc053-375d-4e74-984f-731f43c6f8e5

Lokasyon Electrical & Electronics Engineering

Tarih 2017-03

Örnek Metin Graphene with significant potentials in diverse areas of physical and biological sciences is proposed as a solution to complementary problems of semiconductor and biomedical industries, i.e., the on-chip (OC) interconnect bottleneck and in-body (IB) wireless communications/power transfer (PT), respectively. Emerging nanoscale solutions with radio frequency, optical, ultrasonic, or molecular channels in OC and IB media have various challenges including achievable footprints and frequency, energy consumption, medium dependent features, and interference. In this paper, major challenges are addressed with magneto-inductive (MI) transceivers by combining the advantages of THz operation frequency, unique features of intercalated multi-layer graphene (MLG) coils and range extension with MI waveguides. Our design promises scalable and high performance solutions for the OC interconnect bottleneck while providing biocompatible and universal solutions for challenging IB medium. The proposed solution is theoretically analyzed and numerically compared with the copper-based alternatives, and the practical challenges are discussed. Simulation results achieve high capacity (several Tbit/s) and ultra-low power (500 zJ/bit) wireless communications while providing high (hundreds of kWs) and efficient (109 W/mm2) wireless PT at several millimeters. In addition, unique properties of MLG such as lightweight structure, biocompatibility, current carrying capacity, and planar manufacturability make the solution more promising for challenging environments.

DOI 10.1109/TMBMC.2017.2655022

Cilt 3