Role of graphene nanofluids on heat transfer enhancement in thermosyphon

They observed a decrease in thermal resistance and wall temper-ature difference in a heat pipe using nanofluid compared to pure water.. In the present report, an attempt is made to measur

Original Article

thermosyphon

Sidhartha Dasa,*, Asis Giria, Sutanu Samantaa, S Kanagarajb

a Department of Mechanical Engineering, North Eastern Regional Institute of Science and Technology, Nirjuli, Arunachal Pradesh, 791109, India

b Department of Mechanical Engineering, Indian Institute of Technology, Guwahati, Assam, 781039, India

a r t i c l e i n f o

Article history:

Received 28 October 2018

Received in revised form

21 January 2019

Accepted 22 January 2019

Available online 30 January 2019

Keywords:

Graphene platelet nanoparticle

Thermosyphon

Thermal conductivity

Viscosity

Thermal resistance

a b s t r a c t

The thermophysical properties of graphene nanofluids in thermosyphon have been studied at different power inputs, temperatures and angles of inclination The thermal conductivity of the graphene nano-fluid is found to be 29% higher than that of the deionized water at 45
C The viscosity of the graphene nanofluid increased with the concentration of graphene nanoparticles and decreased with increasing the temperature It is observed that the wall temperature distribution of graphene nanofluid is found to be decreased in comparison to that of deionised water The thermal resistance of thermosyphon is reduced with increasing the power input and irrespective of the inclination angle

© 2019 The Authors Publishing services by Elsevier B.V on behalf of Vietnam National University, Hanoi This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)

1 Introduction

Tremendous demands for higher heat transfer devices exist due

to the advancement of microelectronics, which necessitate better

thermal management solutions A thermosyphon is a device, which

uses the phase transformation of a workingfluid to transport heat

and therefore heat transport by this device is fundamentally higher

than any highly conducting material having same cross section

Thus, the boiling characteristics, vapour pressure, thermal

con-ductivity and surface tension of the workingfluid play an important

role in the performance of thermosyphon Nanofluid, solideliquid

suspension is produced by dispersing nanoparticles with the

workingfluid A lot of research has been carried out to enhance the

thermal performance of the thermosyphon using nanofluids

Noie et al.[1] conducted an experimental study on the

two-phase closed thermosyphon (TPCT) using Al2O3/water nanofluids

The efficiency of TPCT was found to enhance up to 14.7% for a

concentration ranging from 1 to 3 vol.% TPCTfilled with

water-based Al2O3 and TiSiO2 nanofluids was investigated by Kamyar

et al [2] for a nanoparticle loading of 0.01%, 0.02%, 0.05% and

0.075% involving a thermal load ranging from 40 W to 210 W They observed a decrease in the thermal resistance of the heat pipe up to 65% for 0.05 vol.% of Al2O3and 57% for 0.075 vol.% TiSiO4 Kole and Dey[3]examined surfactant free water based copper nanofluids and observed a thermal conductivity enhancement of 15% for 0.5 wt.% at 30
C Further, the nanofluid was used in the wicked heat pipe, which indicated a thermal resistance as low as 27% at higher thermal load Al2O3, CuO and laponite in water caused the decrease

of the performance of heat pipe This was reported by Khandekar

et al [4] It was predicted that nanoparticles entrapment in the grooves of the rough surface was the reason for such behaviour The oscillating heat pipe (OHP) was examined by Qu and Wu [5], by using Al2O3/water and SiO2/water nanofluids, where a reduction in thermal resistance was found for both the workingfluids Using water-based TiO2 and Au nanofluids, Buschmann and Franzke [6] investigated thermal performance of heat pipe A maximum reduction in the thermal resistance of 24% was observed from the experiment The performance of refrigerant based Ti nanofluid was observed in a heat pipe by Naphon et al.[7] An optimum condition was revealed for a heat pipe with 0.1% nano-particle concentration, which provided 1.4 times higher efficiency than the pure refrigerant The experimental study on the Al2O3/ water nanofluid performed by Ho et al.[8]showed an improved heat transfer Moraveji and Razvarz[9]studied the heat transfer rate in the heat pipe with 90
bend using Al2O3/water nanofluid

* Corresponding author.

E-mail addresses: sidhartha_me15@nerist.ac.in (S Das), measisgiri@yahoo.com

(A Giri), suta_sama@yahoo.co.in (S Samanta), kanagaraj@iitg.ernet.in

(S Kanagaraj).

Peer review under responsibility of Vietnam National University, Hanoi.

Contents lists available atScienceDirect Journal of Science: Advanced Materials and Devices

j o u r n a l h o m e p a g e : w w w e l s e v i e r c o m / l o c a t e / j s a m d

https://doi.org/10.1016/j.jsamd.2019.01.005

2468-2179/© 2019 The Authors Publishing services by Elsevier B.V on behalf of Vietnam National University, Hanoi This is an open access article under the CC BY license

Journal of Science: Advanced Materials and Devices 4 (2019) 163e169

They observed a decrease in thermal resistance and wall

temper-ature difference in a heat pipe using nanofluid compared to pure

water

Solomon et al.[10]studied the performance of an anodized TPCT

with refrigerant as workingfluid and found that TPCT performed

better at the 45
inclination Ghanbarpour et al.[11]used silver

based nanofluid in the heat pipe with two layers of screen mesh It

was found that the 60
inclination of the heat pipe was superior to

other inclinations Torii et al.[12]experimentally studied the heat

transfer performance in a circular pipe containing aqueous

sus-pensions of nanoparticles, i.e., diamond, Al2O3and CuO They found

an increase in relative viscosity and better performance compared

to that of pure water

The effect of graphene oxide concentration in water was

re-ported by Hajjar et al.[13] An enhancement of 33.9% in thermal

conductivity was observed with the addition of 0.25 wt.% at 20
C

Ghozatloo et al.[14] examined the thermal performance of

gra-phene nanofluid in shell and tube heat exchanger, where

convec-tive heat transfer coefficient increased by 35.6% at 38
C for 0.1 wt.%

of graphene nanofluid Shadeghinezhad et al [15] observed the

performance of heat pipe with graphene nanoparticles and found a

maximum reduction of 48.14% compared to that of deionized (DI)

water using sintered wick heat pipe It was also found that

maximum effective thermal conductivity enhancements for the

heat pipe with GNP concentration is found to be significant at 60

inclination

Cited literature reveals that there exist a handful of literature,

which uses Al2O3, CuO, TiO2 nanofluid as a working medium in

thermosyphon with forced convection However, compared to other

nanofluids (i.e., Al2O3, CuO, TiO2nanofluids), the effect of graphene

nanofluid in thermosyphon is nominal in the literature Moreover, it

is noticed that very few experimental investigation has been carried

out in a smaller sized circularfinned thermosyphon Graphene is

particularly interesting since it enhances the thermal properties of

basefluid significantly In the present report, an attempt is made to

measure the thermal conductivity and viscosity of graphene

nano-fluid at low concentration along with its thermal performance in

thermosyphon at different heat input and inclinations

2 Materials and methods

2.1 Nanofluid preparation

Graphene platelet nanopowder is procured from Sisco Research

Laboratories Pvt Ltd (GPN Type 1, 55093), which is having 99.5%

purity To prepare the graphene nanofluids, graphene nanoparticles

are mixed with DI water in the required concentration and

mag-netic steering is done with the help of a magmag-netic stirrer for 10 h at

750 rpm at a temperature of 28
C After that Gum Acacia (Fisher

Scientific, CAS No - 9000-01-5) is mixed with nanoparticles in

weight percentage ratio of 0.5:1 The sample thus prepared is then

sonicated for 5 h to form colloid of graphene particles with DI

water To see the sedimentation of the particles, a visualization

method is followed for a period of 30 days and minimal

sedimen-tation is noticed (Fig 2 in the Supplementary File) In the process of

sonication, liquid sample gets heated up and therefore liquid

evaporates The evaporated liquid will escape if sonication bath is

open to atmosphere and hence appropriate cover for the sonication

bath is needed to avoid the escape of evaporated liquid A small

volume of gum acacia is helpful in retaining the nanoparticles in

colloidal form Scanning electron microscope (SEM) picture of

particles is depicted inFig 1, which is made by drying dilute

so-lution over the glass slide SEM picture indicates that particles are

platelet type Concentrations of graphene nanoparticles of 0.02,

0.04, 0.06, 0.08 and 0.10 wt.% are prepared for the study The

advantage of these concentrations is that particle remains in colloid form for days with nominal sedimentation

2.2 Measurement of thermal conductivity and viscosity of graphene nanofluid

For measuring the thermal conductivity of the nanofluids, the KD2 Probe was used (Decagon Devices, Inc.) with a single needle (KS1) which has a size of 1.3 mm diameter and 6 cm long KD2 probe measures the thermal conductivity by the transient hot wire method in which, a thin metallic conducting wire is used for both as

a line heat source and a temperature sensor Thermal conductivity

of liquid is measured by submerging the metallic wire in the liquid Current is passed through the wire and the temperature is moni-tored over time, which is used for measuring the conductivity This

is the basic principle used for the measurement of the thermal conductivity in the KD2 probe To prevent free convection in the fluid, the temperature of fluid was maintained lower than 50
C as suggested in the KD2 Pro Manual Moreover, time duration for taking measurement is also reduced to 60s to avoid any further convection in thefluid

The viscosity of DI water and graphene nanofluid is measured by Rheometer (Physica, MCR 101, Anton Paar) The rheometer consists

of a stationary cylindrical surface and a moving cylindrical bob which are parallel to each other with a small gap and the liquid is kept between them The cylindrical bob is connected to driver motor, which rotates at different speeds and the stationary cylin-drical surface connects to the torque measuring device in order to evaluate the resistance of the sample to the motion

2.3 Thermosyphon and experimental setup The thermosyphon used presently and the experimental setup

is sketched inFig 2aeb A 120 mm long copper tube with an outer diameter of 8 mm and inner diameter of 6 mm is made to form the device The device consists of three sections: (i) 50 mm long evaporator section, (ii) 20 mm long adiabatic section, (iii) 50 mm long condenser section Evaporator section is covered with a heating unit to apply constant heat input Adiabatic section is covered with glass wool placed over the evaporator and it is 20 mm long A 50 mm long condenser section is positioned above the adiabatic section, wherein 23 equally spaced radialfins are placed

to assist natural convection cooling Eachfin has the dimensions of

26 mm outer diameter, 8 mm inner diameter and 1 mm thickness

To measure the thermal performance, T-type thermocouples (i.e., copper-constantan) are positioned on the thermosyphon at the locations of 10 mm, 20 mm, 45 mm, 60 mm, 72 mm, 95 mm,

115 mm and 119 mm from the evaporator end At the location of

72 mm, 95 mm, and 115 mm, thermocouples are positioned on the surface of thefins The remaining five thermocouples are placed on the surface of the thermosyphon Data acquisition system (Unilog Pro Plus, PPI) is used to collect the temperature of different loca-tions in the thermosyphon The uncertainty in the measurement of temperature is calculated by calibrating it against a standardfluke made digital thermometer (Fluke 17B) having a resolution of 0.1
C

at a temperature range from 25
C to 100
C The maximum vari-ation in the measurement of temperature is found to be±0.5
C. The experiment is being conducted with graphene nanofluid at different weight percentage The input heat to thermosyphon is being made to the desired level by the use of an autotransformer and measured with wattmeter (Multi-Span) The setup is operated for 45 min before any measurement during which time steady state

is attained which means the temperature does not change more than±0.1
C at a given heat input and the temperatures of the thermosyphon are recorded using data logger connected with‘T’

S Das et al / Journal of Science: Advanced Materials and Devices 4 (2019) 163e169 164

type thermocouples Each experiment is repeated three times for

its repeatability Experiments are conducted for 4 W, 8 W and 12 W

Heat losses from the evaporator section by radiation and free

convection are neglected Thermal performance of thermosyphon

is tested for vertical as well as for inclined position Ambient

temperature during the experiment remains 25
C The uncertainty

in resistance between the evaporator and the condenser is

calcu-lated[3]by

DR

ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi

DQin

Qin

2 þ

DðDTÞ

DT

2 s

(1)

The maximum uncertainty in the measurement of the heat input (Qin) and total resistance is around 0.79% and 1.80% which are less than 1% and 2%, respectively

3 Results and discussion 3.1 Thermal conductivity Water based graphene nanofluid is prepared for different weight concentration of graphene particles and its conductivity is measured Measured conductivity variation of graphene nanofluid with temperature is exemplified inFig 3a From thefigure, it may

be noted that conductivity increases with temperature for all weight concentration of graphene nanofluid Further, it is identified that as weight concentration increases, the thermal conductivity of nanofluid increases at a fixed temperature Moreover, thermal conductivity of graphene nanofluid is always higher than DI water Thermal conductivity enhancement at the highest concentration (i.e., 0.1 wt.%) is about 17% of water conductivity at a temperature of

25
C, while the same enhancement at 45
C is around 29% of water conductivity It is also noticed from the published data of Ahammed

et al [16] that similar enhancement of 37.2% was noted for 0.15 vol.% of graphene nanofluid at a temperature of 50
C

Fig 1 SEM image of Graphene platelet nanoparticle.

finned thermosyphon; (b) Experimental setup.

S Das et al / Journal of Science: Advanced Materials and Devices 4 (2019) 163e169 165

compared to that of DI water at the same temperature The

con-ductivity of graphene nanofluids is enhanced by 7% by changing the

temperature from 25 to 45
C for 0.02 wt.% Thermal conductivity of

0.64 W/mK is observed for 0.04 wt.% of graphene nanofluid at 25
C,

which is 4.7% higher compared to that of 0.05 vol.% at 20
C[16] In

addition, the thermal conductivity of graphene nanofluid having

0.10 wt.% is noted to be 0.81 W/mK at 45
C and it is 8.3% less in

comparison to the thermal conductivity of 0.15 vol.% of graphene

nanofluid at 50
C[16].

As the concentration of weight of graphene particle increases,

the random motion of the graphene particles is enhanced in the

basefluid It is expected that the movement of such particles

in-duces the collision between nanoparticles At higher temperature,

these collisional effects might be more and thus, the thermal

con-ductivity of nanofluid is found to be improved In addition, when

the concentration increases, the conduction electron (i.e., free

electrons available in the atoms, such as metal atoms, which are

primarily accountable for thermal conductivity) is enhanced since

the distance between atoms in afixed volume of graphene

nano-fluid decreases Whenever concentration of nanoparticle is

increased, the common surface areas between atoms of

nano-particles and the base liquid are enhanced This leads to an

enhancement in thermal conductivity As the temperature is

enhanced, the thermal conductivity is also enhanced This is

possibly due to two reasons, (1) basefluid thermal conductivity is

enhanced due to increased Brownian motion and (2) conduction

electrons will be positioned at a high energy level causing electron

to move faster and thus heat will be transported at a faster rate

which leads to higher thermal conductivity As the molecules in the

liquid are closely spaced they yield stronger intermolecular force

The heat conduction in liquid occurs due to the molecular collision and diffusion In general, the thermal conductivity of liquid de-creases with temperature However, water is an exceptional case, as thermal conductivity gets enhanced with temperature In nano-fluid, solid particle thermal conductivity must also be taken into account The thermal energy is being transferred by phonons in non-metallic compound and free electrons in metallic compound Since graphene has both phonons and free conduction electron, both phonons and free electron influence the thermal conductivity

of graphene nanofluid Hence, three factors influence the enhancement of thermal conductivity of graphene nanofluid: (i) phonons (vibrations), (ii) free electron, (iii) rapid molecular colli-sion and diffucolli-sion A similar observation is also made by Ahammed

et al.[16] Presently measured thermal conductivity of graphene nanofluid is compared with Nan's model[17]and it is expressed in

Eq.(2)as

knf ¼ kbf3þ 4½2b11ð1  L11Þ þb33ð1  L33Þ

where Liiand Ø are the geometrical factors and the volume fraction

of particles, respectively, andbiiis defined as:

bii¼ kp kbf

kbf þ Lii



kp kbf

Maximum deviation between the theoretical and experimental conductivity is noted to be 8.5% for 0.10 wt.% of graphene nanofluid Overall agreement between theoretical model (Nan's) with the measured result is reasonably good and is presented inFig 3b 3.2 Viscosity

Viscosity of water increases with the addition of graphene particles which is depicted inFig 4a In the present study, the viscosity enhancement of graphene nanofluid for the highest concentration of 0.10 wt.% is around 175% higher in comparison to

DI water at 20
C InFig 4a, viscosity of graphene nanofluid is also found to decrease with temperature and this decrease is as high as 25% for a concentration of 0.10 wt.% of nanofluids Rheological study is made to characterize the graphene nanofluids.Fig 4bec depicts such behaviour in the form of shear rate deformation at different temperature and it is found to be linear Linear deforma-tion rate only indicates that graphene nanofluid considered pres-ently is Newtonian in behaviour for all the temperature attempted

in the present study

3.3 Temperature distribution

Fig 5aec represents the temperature distribution of the ther-mosyphon at a distance of 45, 60 and 119 mm for the evaporator, adiabatic and condenser section respectively at different heat input and inclination angle It can be observed from thefigures that the wall temperature distribution of DI water is higher compared to that of graphene nanofluid and as the concentration increases, wall temperature is decreased further

It is noted fromFig 5a, the wall temperature of DI water is 42.5
C and with the addition of 0.10 wt.% of graphene nanofluid, there is a decrease of 13.9% in the evaporator wall temperature for a heat input of 4 W, 60
inclination In addition, it can also be observed from the results of Kamyar et al.[2] that a maximum of 24.53% decrease in wall temperature is found at 0.05 vol.% of Al2O3 nanofluid compared to DI water at 40 W heat input Moreover, as the inclination angle increases from 30
to 60
, the average wall temperature of the evaporator section decreases at 60
inclination

Fig 3 (a) Thermal conductivity variation of nanofluid with temperature for different

weight percentages, (b) Comparison of thermal conductivity variation of graphene

nanofluid with different temperature and concentration (Nans Model).

S Das et al / Journal of Science: Advanced Materials and Devices 4 (2019) 163e169 166

After 60
inclination, average evaporator temperature increases

again Similar trend is observed for adiabatic and condenser section

of the thermosyphon (Fig 5bec) Gravitational effect on

conden-sate return to the evaporator is the primary reason behind this

Gravitational effect of condensate return enhances with the

in-crease in inclination angle, which causes the enhancement of liquid

return Hence, at the inclination angle 60
, evaporator temperature

is low Gravitational effect is maximum at 90
, which causes the

presence of more liquid in the evaporator section creating a

flooding condition This causes an increase in evaporator

temper-ature A similar observation is also made by Moraveji and Razvarz

[9] The wall temperature distribution in thermosyphon for 12 W

heat input also follows the same trend Therefore, better thermal

performance may also be observed with graphene nanofluid Evaporator wall temperature distribution for 60
inclination is lower compared to any other inclination angle Therefore, ther-mosyphon is expected to perform better at 60
inclination It is observed fromFig 5d that the evaporator temperature of graphene nanofluid is lower than DI water wall temperature and there is a decreasing temperature gradient from the evaporator section to the condenser section Moreover, there is a reduction in temperature difference between the evaporator and condenser section of the thermosyphon with the increase in concentration of graphene nanofluid At a heat input of 12 W, 60
inclination, temperature difference between the evaporator and condenser section for DI water is 10.9% whereas with the addition of 0.10 wt.% of graphene nanofluid the temperature difference is reduced to 6.4% This is possibly due to porous layer formation on the surface of thermo-syphon This creates more nucleation site The increase in number

of nucleation site enhances the boiling characteristics by intro-ducing significantly large number of small nucleation bubbles Formation of small nucleation bubble introduces lower thermal resistance due to continuous rewetting of evaporator, while on the other hand, large size bubble causes a high thermal resistance to heatflow A similar enhancement is noted by Singh et al.[18]in connection with anodized thermosyphon

3.4 Thermal resistance The thermosyphon performance may be relatively estimated by the thermal resistance[19](R) defined as follows:

R¼Te Tc

where Teand Tcare the evaporator and condenser temperatures, respectively Q in Eq.(4)represents heat input Variation of thermal resistance with heat input is shown in Fig 6aed for different inclination of the thermosyphon It is understood from thefigures that thermal resistance is decreased sharply with the increased heat input for all cases of nanofluids and DI water Around 72% decrease in thermal resistance is observed by increasing heat input from 4 to 12 W for the highest concentration of nanofluid and at all inclinations of TPCT Thermal resistance is decreased by around 25% compared to DI water for a heat input of 4 W, at a concentration of 0.10 wt.% of graphene nanaofluid at 30
inclination of TPCT The thermal resistance of TPCTfilled with graphene nanofluid reduces considerably due to the reduction of evaporator temperature and simultaneous increase of condenser wall temperature Singh et al

[18], Shukla et al.[19]and Riehl and Santos[20]made similar types

of observation in their studies Further, it is noted that the thermal resistance of nanofluid filled TPCT is lower than the DI water filled TPCT Moreover, deposition of graphene nanoparticles on the evaporator surface causes nucleation site to increase and this im-proves the regime of nucleate boiling Further, due to the deposi-tion of nanoparticles, there occurs a change in surface wettability

In addition, turbulence is being generated at higher heat input in the graphene nanofluid due to the movement of nanoparticle in the fluid A similar observation is being made by Shukla et al.[19]in their study of heat pipe using CuO nanofluid More nucleation sites are created as the nanoparticle deposits on the surface of the evaporator The performance of evaporator with the deposition of nanoparticles highly depends on bubble departure diameter, nucleation site density, frequency of bubble departure and ther-mophysical properties of the working medium The performance of the evaporator of TPCTfilled with graphene nanoparticle may be

Fig 4 Variation of viscosity (a) Viscosity of Graphene nanofluid at different

temper-ature; (b) Rheological behaviour of nanofluid at different weight percentage for 20
C;

(c) Rheological behaviour of nanofluid at different weight percentage for 50
C.

S Das et al / Journal of Science: Advanced Materials and Devices 4 (2019) 163e169 167

described through the correlation proposed by Mikic-Rohsenow

[10]as under:

NaAeDb ffiffiffi

f

p ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi

pklrlCl

where heis the coefficient of heat transfer, Aeis the evaporator area,

Nais the nucleation site density, Dbis the departure diameter of the

bubble, f is the frequency of bubble departure kl,rland Clare the conductivity, density and specific heat, respectively Because of nanoparticle deposition, nucleation site density increases manifold due to the formation of porous layer Bubble departure diameter may decrease due to decrease in surface tension at higher temperature, but bubble departure frequency and effective surface area will in-crease Overall effects cause an improvement in thermal perfor-mance It is found that inclination angle has nominal influence on

Fig 5 Temperature distribution at different section of the thermosyphon against varying heat input, inclination angle and different concentration of graphene nanofluid (a) Evaporator section, (b) Adiabatic section, (c) Condenser section, (d) Wall temperature distribution of the thermosyphon against different heat input, inclination angle and different concentration of graphene nanofluid.

Fig 6 Thermal resistance variation of thermosyphon with heat load for different nanoparticles concentrations at (a) 30
angle of thermosyphon; (b) 45
angle of thermosyphon; (c)

S Das et al / Journal of Science: Advanced Materials and Devices 4 (2019) 163e169 168

the performance of thermosyphon although evaporator, adiabatic

and condenser section temperature is lower at 60⁰ inclination This is

in contrary to other studies available in the literature in which higher

performance is noted with 45
and 60
inclinations of

thermosy-phon Naphon et al.[7]and Ghanbarpour et al.[11]observe 60

inclination performs better However, Singh et al.[18], and Solomon

et al.[10]observe better performance with 45
inclination of TPCT It

may be noted that Khandekar et al.[4]observe a decrease in thermal

performance using nanofluid Almost same thermal resistance is

observed irrespective of inclination angles

4 Conclusions

Water based graphene nanofluid has been characterized through

SEM, thermal conductivity and viscosity measurement SEM image

reveals that the graphene particles are platelet type Following

conclusions may be drawn from the present investigation:

 An enhancement in thermal conductivity of around 17% is

noticed compared to that of DI water for 0.10 wt.% of graphene

nanofluid at a temperature of 25
C, while the same is around

29% at 45
C Therefore, thermal conductivity enhancement is

temperature dependent for the involved operating range

 The viscosity of the graphene nanofluid is noted to be enhanced

by 175% at 0.10 wt % for 20
C However, viscosity is decreased

by 25% when temperature increases from 20
C to 50
C

Gra-phene nanofluid shows a Newtonian behaviour

 Use of graphene nanofluid in thermosyphon indicates a

reduc-tion in the wall temperature distribureduc-tion and consequently

thermal resistance decreases At a heat input of 4 W, 60

incli-nation of the thermosyphon, maximum wall temperature

re-ported is 42.5
C for DI water and with the application of

0.10 wt.% of graphene nanofluid there is a reduction of 13.9% in

the evaporator wall temperature

 Moreover, increasing the heat input from 4 to 12 W, a reduction

resistance of around 72% is noted for the highest concentration

of nanoparticle The thermal resistance of thermosyphon is

observed to be almost same irrespective of inclination angles

Conflict of interest

None

Appendix A Supplementary data

Supplementary data to this article can be found online at

https://doi.org/10.1016/j.jsamd.2019.01.005

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