2D-Based Nanofluids: Materials Evaluation and Performance

Research output: Chapter in Book/Report/Conference proceedingChapter (peer-reviewed)

Abstract

Advancement in technology demands the successful utilization of energy and its management in a greater extent. Thermal energy management plays a crucial role from high-payload electrical instruments to ultra-small electronic circuitries. The advent of nanofluids that happened in the 1990s successfully addressed the low thermal efficiency of conventional fluids in a significant manner. The ground-breaking report on the concept of “nanofluids for thermal management” led to the development of numerous thermal fluids using nanofillers of ceramics, metals, semiconductors, various carbon nanostructures, and composite materials. Later, demonstration of two-dimensional (2D) nanomaterials and their successful bulk synthesis led to the development of highly efficient fluids with even very low filler fractions. Introduction of 2D materials into fluids also brought out the multifunctional aspects of fluids by using them in tribology. In this chapter, we narrate the advances in thermal nanofluids and the development of novel fluids with the discovery graphene. Multifunctional aspects of these fluids are discussed here. To support the experimental observation, a theoretical platform is discussed and its predictions are correlated on the basis of existing data. The chapter has been concluded with a brief discussion on futuristic aspects of nanofluids in reallife applications. This chapter aims to focus on the description of the thermal transport, tribological behavior, and aspects that involve the use of 2D-based nanofluids, from various 2D nanostructures such ash-BN, MoS2, WS2, graphene, among others. The homogeneous nanoparticle distribution within
Original languageEnglish
Title of host publicationTwo-dimensional Materials - Synthesis, Characterization and Potential Applications
EditorsPramoda Kumar Nayak
Place of PublicationCroatia
PublisherInTech
Chapter8
Pages153 - 198
Number of pages46
Edition1
ISBN (Electronic)978-953-51-2555-6
ISBN (Print)978-953-51-2554-9
DOIs
Publication statusPublished - 31 Aug 2016

Fingerprint

Fluids
Graphite
Ashes
Nanostructures
Tribology
Cermets
Energy management
Thermal energy
Nanostructured materials
Temperature control
Fillers
Demonstrations
Carbon
Semiconductor materials
Nanoparticles
Hot Temperature
Composite materials

Cite this

Taha-Tijerina, J. (2016). 2D-Based Nanofluids: Materials Evaluation and Performance. In P. Kumar Nayak (Ed.), Two-dimensional Materials - Synthesis, Characterization and Potential Applications (1 ed., pp. 153 - 198). Croatia: InTech. https://doi.org/10.5772/64760
Taha-Tijerina, Jaime. / 2D-Based Nanofluids: Materials Evaluation and Performance. Two-dimensional Materials - Synthesis, Characterization and Potential Applications. editor / Pramoda Kumar Nayak. 1. ed. Croatia : InTech, 2016. pp. 153 - 198
@inbook{187d83d07d4e4e5697bcbbaa1b4d89f0,
title = "2D-Based Nanofluids: Materials Evaluation and Performance",
abstract = "Advancement in technology demands the successful utilization of energy and its management in a greater extent. Thermal energy management plays a crucial role from high-payload electrical instruments to ultra-small electronic circuitries. The advent of nanofluids that happened in the 1990s successfully addressed the low thermal efficiency of conventional fluids in a significant manner. The ground-breaking report on the concept of “nanofluids for thermal management” led to the development of numerous thermal fluids using nanofillers of ceramics, metals, semiconductors, various carbon nanostructures, and composite materials. Later, demonstration of two-dimensional (2D) nanomaterials and their successful bulk synthesis led to the development of highly efficient fluids with even very low filler fractions. Introduction of 2D materials into fluids also brought out the multifunctional aspects of fluids by using them in tribology. In this chapter, we narrate the advances in thermal nanofluids and the development of novel fluids with the discovery graphene. Multifunctional aspects of these fluids are discussed here. To support the experimental observation, a theoretical platform is discussed and its predictions are correlated on the basis of existing data. The chapter has been concluded with a brief discussion on futuristic aspects of nanofluids in reallife applications. This chapter aims to focus on the description of the thermal transport, tribological behavior, and aspects that involve the use of 2D-based nanofluids, from various 2D nanostructures such ash-BN, MoS2, WS2, graphene, among others. The homogeneous nanoparticle distribution within",
author = "Jaime Taha-Tijerina",
year = "2016",
month = "8",
day = "31",
doi = "10.5772/64760",
language = "English",
isbn = "978-953-51-2554-9",
pages = "153 -- 198",
editor = "{Kumar Nayak}, {Pramoda }",
booktitle = "Two-dimensional Materials - Synthesis, Characterization and Potential Applications",
publisher = "InTech",
address = "Croatia",
edition = "1",

}

Taha-Tijerina, J 2016, 2D-Based Nanofluids: Materials Evaluation and Performance. in P Kumar Nayak (ed.), Two-dimensional Materials - Synthesis, Characterization and Potential Applications. 1 edn, InTech, Croatia, pp. 153 - 198. https://doi.org/10.5772/64760

2D-Based Nanofluids: Materials Evaluation and Performance. / Taha-Tijerina, Jaime.

Two-dimensional Materials - Synthesis, Characterization and Potential Applications. ed. / Pramoda Kumar Nayak. 1. ed. Croatia : InTech, 2016. p. 153 - 198.

Research output: Chapter in Book/Report/Conference proceedingChapter (peer-reviewed)

TY - CHAP

T1 - 2D-Based Nanofluids: Materials Evaluation and Performance

AU - Taha-Tijerina, Jaime

PY - 2016/8/31

Y1 - 2016/8/31

N2 - Advancement in technology demands the successful utilization of energy and its management in a greater extent. Thermal energy management plays a crucial role from high-payload electrical instruments to ultra-small electronic circuitries. The advent of nanofluids that happened in the 1990s successfully addressed the low thermal efficiency of conventional fluids in a significant manner. The ground-breaking report on the concept of “nanofluids for thermal management” led to the development of numerous thermal fluids using nanofillers of ceramics, metals, semiconductors, various carbon nanostructures, and composite materials. Later, demonstration of two-dimensional (2D) nanomaterials and their successful bulk synthesis led to the development of highly efficient fluids with even very low filler fractions. Introduction of 2D materials into fluids also brought out the multifunctional aspects of fluids by using them in tribology. In this chapter, we narrate the advances in thermal nanofluids and the development of novel fluids with the discovery graphene. Multifunctional aspects of these fluids are discussed here. To support the experimental observation, a theoretical platform is discussed and its predictions are correlated on the basis of existing data. The chapter has been concluded with a brief discussion on futuristic aspects of nanofluids in reallife applications. This chapter aims to focus on the description of the thermal transport, tribological behavior, and aspects that involve the use of 2D-based nanofluids, from various 2D nanostructures such ash-BN, MoS2, WS2, graphene, among others. The homogeneous nanoparticle distribution within

AB - Advancement in technology demands the successful utilization of energy and its management in a greater extent. Thermal energy management plays a crucial role from high-payload electrical instruments to ultra-small electronic circuitries. The advent of nanofluids that happened in the 1990s successfully addressed the low thermal efficiency of conventional fluids in a significant manner. The ground-breaking report on the concept of “nanofluids for thermal management” led to the development of numerous thermal fluids using nanofillers of ceramics, metals, semiconductors, various carbon nanostructures, and composite materials. Later, demonstration of two-dimensional (2D) nanomaterials and their successful bulk synthesis led to the development of highly efficient fluids with even very low filler fractions. Introduction of 2D materials into fluids also brought out the multifunctional aspects of fluids by using them in tribology. In this chapter, we narrate the advances in thermal nanofluids and the development of novel fluids with the discovery graphene. Multifunctional aspects of these fluids are discussed here. To support the experimental observation, a theoretical platform is discussed and its predictions are correlated on the basis of existing data. The chapter has been concluded with a brief discussion on futuristic aspects of nanofluids in reallife applications. This chapter aims to focus on the description of the thermal transport, tribological behavior, and aspects that involve the use of 2D-based nanofluids, from various 2D nanostructures such ash-BN, MoS2, WS2, graphene, among others. The homogeneous nanoparticle distribution within

U2 - 10.5772/64760

DO - 10.5772/64760

M3 - Chapter (peer-reviewed)

SN - 978-953-51-2554-9

SP - 153

EP - 198

BT - Two-dimensional Materials - Synthesis, Characterization and Potential Applications

A2 - Kumar Nayak, Pramoda

PB - InTech

CY - Croatia

ER -

Taha-Tijerina J. 2D-Based Nanofluids: Materials Evaluation and Performance. In Kumar Nayak P, editor, Two-dimensional Materials - Synthesis, Characterization and Potential Applications. 1 ed. Croatia: InTech. 2016. p. 153 - 198 https://doi.org/10.5772/64760