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View Journal  | View Issue
Effect of temper
aFraunhofer-Institute for Interfacial Enginee

70569 Stuttgart, Germany. E-mail: solyomka
bSchool of Food Technology, University of C

Cite this: RSC Adv., 2020, 10, 16783

Received 17th December 2019
Accepted 14th March 2020

DOI: 10.1039/c9ra10639a

rsc.li/rsc-advances

This journal is © The Royal Society o
ature and moisture contents on
dielectric properties at 2.45 GHz of fruit and
vegetable processing by-products

Katalin Solyom, *a Pilar Rosales Lopez,a Patricia Esquivel,b Ana Luciaa and Vásquez-
Caicedoa

Microwave heating is a part of several food processing unit-operations, while also emerging as a processing

technology for by-products. Process efficiency depends on dielectric properties; however, data of these

by-products are scarce in literature. The present study is focused on the effect of temperature and

moisture content (M) on the dielectric constant (30) and loss (300) of carrot waste, apple pomace,

pineapple peel and spent coffee grounds at 2.45 GHz. Results on 30 showed moisture-dependent

temperature effect with an inflection point at M ¼ 50.3%. The 300 increased with increasing M up to 60%

and decreased at higher moisture levels. Results at different temperatures were significantly affected by

the composition of the studied materials and thus the calculated power penetration depth. Although

fresh food dielectric properties are available in literature, the data is not always suitable to estimate food

waste properties as processing may cause compositional changes. The obtained results support

microwave process optimization in the field of food-waste valorization.
Introduction

Fruit and vegetable processing industries produce millions of
tons of by-products, including peels, seeds, stones, residual
pulp and others. If not disposed of or treated, these waste
products are considered environmental hazards due to the
emission of greenhouse gases during decomposition. Moreover,
the valorization of these waste products has been discussed due
to their potential as bioactive compound sources.1 Several
efforts have been described in order to take advantage of food
wastes. The extraction of carotenoids from carrot peels,2 the
valorization of apple pomace by the extraction of valuable
compounds,3 the extraction of bioactive compounds and
glycosides from pineapple peels4 as well as the potential of
spent coffee grounds as a source of polyphenols5 are some
examples of the broad research focused on exploiting the
industrial potential of by-products from the fruit and vegetable
processing industries. These bioactives gained importance due
to their association with several health benets but extraction
methods are still a challenge.6

Modern green extraction techniques have been developed
with the goal of exploiting bioactive compounds using more
eco-friendly, efficient and cost-effective techniques.6

Among the different novel extraction technologies,
microwave-assisted extraction has emerged as a promising
ring and Biotechnology, Nobelsrtaße 12,

talin@gmail.com

osta Rica, 2060 San Pedro, Costa Rica

f Chemistry 2020
alternative providing highly efficient recovery due to shorter
extraction time and lower solvent usage.6–8 Moreover, the
enhancement of the microwave combustion efficiency of food
waste has been assessed, and the effects and impact on the food
components have been broadly reviewed.9,10 For the application
of microwave technologies, research on the DPs of the materials
under study is required.11 Besides comprehensive studies on
optimized process conditions for both extraction and drying
purposes using microwaves, it is essential to know how the
materials in question interact with the electromagnetic eld at
which they are subjected to in order to facilitate the proper
microwave reactor design on a larger scale.

This interaction is described by the complex dielectric
permittivity (eqn (1)–(3)) of the material.12

3 ¼ 303r (1)

3r ¼ 3
0
r + j3 00

r (2)

tan d ¼ 3
00
r

3
0
r

(3)

dp ¼ c

2pf

ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
230r

" ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
1þ

�300r
3
0
r

�2
s

� 1

#vuut
(4)

In eqn (1), 30 and 3r refer to the free space permittivity and
the complex permittivity, respectively. eqn (2) shows the real
RSC Adv., 2020, 10, 16783–16790 | 16783

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part of the complex permittivity, i.e., dielectric constant
(3 0
r), which corresponds to the energy stored in the material

when an electric eld is applied and the imaginary part
(3 00
r ) corresponding to the energy is converted into heat. The

ratio between the imaginary and the real part is tan d, the
tangent loss (eqn (3)), which measures the ability of the food
matrix to absorb microwave energy and dissipate heat to the
surrounding molecules, being responsible for the efficiency of
microwave heating. The tangent loss also plays an important
role in the determination of the penetration depth of microwave
power (eqn (4)), which is dened as the depth where the power
is reduced to 1/e (e ¼ 2.718) of the power entering the surface of
the material. Through the calculation by eqn (4), the penetra-
tion depths (dp) are given in meters, where c is the speed of light
in free space (3 � 108 m s�1), and f is the frequency in Hz.

Chemical composition, seasonal variation, physical struc-
ture, frequency, temperature and moisture content affect most
of the dielectric properties (DP) of the foodmatrix. For vegetable
and fruit samples, the dielectric constant and conductivity
largely depend on the moisture content, as inuenced by
frequency, temperature, density and particle size.13,14 These
characteristics may vary during the microwave process as the
material undergoes physical and perhaps, chemical changes
(e.g. moisture content, temperature and salt concentration),
which would affect its interaction with the dielectric eld.15

Thus, these factors must be taken into account when charac-
terizing the dielectric properties of the sample.

Although there is available literature on the DP of fresh
vegetables and fruits, considering changes in moisture and
temperature,16–18 comprehensive studies on the DPs of by-
products from fruit and vegetable processing are still scarce.
Therefore, the aim of this study is to observe the direct effects of
temperature and moisture content on the DP of the selected
wastes at 2.45 GHz, while taking into consideration the
changing volume fraction of the product.
Table 1 Experimental design for the dielectric properties measure-
ment of carrot waste (CW), apple pomace (AP), pineapple peer (PP) and
spent coffee grounds (SCG) at different moisture (M) and temperature
(T) levels

Carrot
waste

Apple
pomace

Pineapple
peel

Spent coffee
grounds

Moisture (%) 90.4 77.8 86.7 58.2
69.3 61.0 69.0 48.2
64.6 51.1 54.0 42.6
31.6 31.8 38.2 23.5

Temperature (�C) 27.1 24.4 23.0 22.2
40.9 42.6 42.2 34.2
56.9 59.0 58.9 43.5
68.3 74.6 72.5 51.8
Experimental
Raw material

Carrot waste (CW). Carrot waste was prepared in the labo-
ratory for experimentation. Taking into account that the carrot
waste was about 30% of the carrot without leaves,19 6 kg of
carrot from a local supermarket was used for the experiments.
Both extremes of the root were cut and the rest was scrapped,
obtaining two kilograms of waste in total. The proportion of
defected chunks, by decision, were one-sixth of the total waste
mass, the rest were scrapped peels and both extremes of the
root. Homogeny samples were obtained by chopping using
a household appliance (Quad blade chopper, Kenwood CH580,
500 W, 0.5 L) for 10 s at a low speed for carrot waste.

Apple pomace (AP). Apple pomace was obtained from the
Hohenheim University, Plant Foodstuff Technology and Anal-
ysis Department as a residue of the production of apple juice.
The total residue was a mixture of 4 types of apple: Jonagold,
Braeburn, Boskop and Pink lady, and it contained peels,
pomace and seeds. Sample homogeneity was obtained by
16784 | RSC Adv., 2020, 10, 16783–16790
chopping using a household appliance (used as well for CW) for
20 s.

Pineapple peel (PP). Approximately 10 kg of Golden extra
pineapples (the sweet type) were bought at a local supermarket
(ca. 8 pineapples without leaves) and subsequently washed with
cold water. In accordance with previous studies, the mass of the
chopped peels obtained was approximately 3.3 kg, representing
one-third of the total mass.19 Due to their roughness, the peels
were chopped for 20 s as described for CW and AP.

Spent coffee ground (SCG). Coffee residues (100% Arabica-
harmonisch coffee Hochland Kaffee Hunzelmann GmbH &
Co. KG) were collected from the cafeteria at the Fraunhofer
Campus IZS in Stuttgart. Spent from fresh milled and brewed
coffee was further used as samples for this study.

All raw materials were well mixed and distributed into bags
of 250 grams each, and stored at �20 �C. Samples were thawed
at 4 �C overnight before analysis.

Moisture content determination

The moisture content of the samples (approx. 3 g), was deter-
mined in triplicate with an infrared moisture analyzer (MB45
Moisture Analyzer, Ohaus, Pine Brook NJ, USA), programmed to
ascend gradually to 105 �C and switch-off automatically 60 s
aer the mass difference is lower than 1 mg. The moisture
content of the samples was given in weight percent (wt%).

Samples for determining the effect of moisture content, were
prepared in a hot-air drying oven (Binder FD53, drying oven
with forced convection) at 80 �C in order to obtain three levels of
moisture, different from the initial moisture content (Table 1).
Drying times corresponding to the desired moisture level were
previously determined (data not presented) and applied in this
study.

Temperature determination

Samples for determining the effect of temperature were
prepared at room temperature, followed by heating for 20 min
in a hot-air drying oven at 50, 75, 100 �C. To enable better
control of the temperature aer the heating process the samples
were covered with an aluminium foil. The exact temperature
wasmeasured during the determination of dielectric properties.
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Density measurement

Particle density. The sample density was measured in trip-
licate in a glass pycnometer, lled with the sample at different
moisture contents and distilled water.

Bulk density. Due to the preparation method of the raw
materials, particulate forms were obtained and were studied as
a bulk material. Each sample had the same weight and bulk
volume in the examining tubes. The bulk density of these
samples was calculated as follows (eqn (5)):

rb ¼
mvþs �mv

mvþw �mv

(5)

where rb is the bulk density,m(v+s) is the mass of the vial and the
sample,m(v+w) is the mass of the vial and water andmv is the vial
mass. The volume was estimated with distilled water (density ¼
1 g mL�1), so the mass measurements can be directly converted
into volume dimension.
Dielectric properties (DP) measurement

Dielectric Measurement Kit mWaveAnalyzer (Püschner GmbH,
Bremen, Germany) using a cavity perturbation method at 2.45
GHz was applied for the determination of DP. The measure-
ment kit (Fig. 1) consists of A “Microwave Analyzer” composed
of a microwave generator, a microwave receiver and a USB data
acquisition system and an “Open-ended Coaxial Probe Cavity”
made of high-end stainless steel. Polypropylene tubes (D ¼ 12
mm, H ¼ 75 mm) containing exact mass (between 1.70 and
4.22 g, regarding waste material and moisture content) were
used to t a constant volume of the material, which was placed
into the cavity. The maintenance of the exact material amount
between measured replicates is of the highest importance as it
directly inuences the bulk density in the measurement tubes
and the accuracy of the measurement. From the determined
resonant frequency and the quality factor of the empty and l-
led cavity, the complex permittivity was calculated through the
supplied soware (Measurement Kit, Vials v3.01).
Experimental design

Due to the nature of the raw materials and former experience,20

large deviations were expected from the measurements.
Therefore, it was necessary to apply an extensive experimental
design including several repetitions.

A full factorial design was applied for two factors, tempera-
ture (T [�C]) and moisture (M [%]), each at four levels (Table 1).
Fig. 1 Dielectric measurement device.

This journal is © The Royal Society of Chemistry 2020
The highest moisture was the initialM level of the raw material,
and further 3 points were achieved via drying. The lowest
temperature was room temperature, and further three T levels
were achieved via heating. The experimental design included 18
measurement points: 16 points with the moisture (M1–M4) and
temperature (T1–T4) combination, and two additional experi-
ments forM3 and T3. Each measurement point was measured in
ve replicates.

Statistical analysis

The dielectric properties of ve replicates were measured and
evaluated using one-way ANOVA (p # 0.05) in order to deter-
mine if there was a signicant effect of the temperature and
moisture content. Deected results from the replicates were
eliminated (never more than two) by applying the Grubb's test.

In addition, M3–T3 experiments were repeated three times
and were analyzed using one-way ANOVA (p # 0.05) to support
the premise of no signicant difference between the three trials.
Statistical analysis was performed using OriginLab® 2015
(OriginLab Corporation Northampton, Massachusetts, USA).
Linear and polynomial regression on experimental data such as
the calculation of correlation coefficient was performed with
Microso Excel® using the least squares method. The main text
of the article should appear here with appropriate headings.

Calculation

The used waste material was present as a particle-air mixture in
the measurement tubes, in which fractions may vary at different
moisture content and temperature levels. The DP measurement
procedure provided a result of the material, which was present in
the measurement cavity. Therefore, the measured data had to be
evaluated through an air-particle mixing equation in order to
extract reliable data on the characteristics of the pure material.
Based on previous experience on grape marc,20 the complex
refractive indexmixture equation (CRIM) was found to be suitable
for food by-products and thus used in this study (eqn (6)):ffiffiffiffiffi

3m
p ¼ v1

ffiffiffiffi
31

p þ v2
ffiffiffiffi
32

p
(6)

where 3m refers to the dielectric property of the air-material
mixture, 31 and 32 correspond to the air and material phases,
and n1 and n2 refer to their volume fractions (porosity) in the
sample.

Such correlation between experimental data and suitable
models are widely used in literature in order to obtain compa-
rable results on the dielectric properties of porous materials.21

Measured data were obtained from experimental sets, where
the bulk density and particle density were maintained close to
each other in order to reach the highest correlation between
modeled and measured values. Estimated results of pure
material are presented and discussed throughout the study.

Results and discussion
Effect of moisture on dielectric constant

Results showed a similar increasing tendency with increasingM
for all studied material at all temperatures (Fig. 2). This
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Fig. 2 Effect of moisture on food waste dielectric constant at all
temperature levels.

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phenomenon can be attributed to the increase in free water
available in the matrix, moving 30 towards the properties of pure
water, 30 ¼ 80.14,22 In the case of CW, AP and PP, the same linear
approximation (Fig. 2, eqn (7)) was found with the correlation
coefficients of 0.972, 0.973 and 0.985, respectively, independent
of their matrix.

3
0
CW;AP;PP ¼ 0.84M � 12.07 (7)

where 3
0
CW;AP;PP is the estimated dielectric constant of carrot

peel, apple pomace and pineapple peel, and M is the moisture
content.

Calay et al.23 derived predictive equation from available
experimental data for various food matrixes, including fresh
fruit and vegetable as well (eqn (8)):

3’ ¼ 2.14 � 0.104T + 0.808M (8)

The equation to estimate 30 of Calay's study (eqn (7))23 ts
well with the experimental data of our study: correlation coef-
cients of 0.976, 0.974 and 0.985 for CW, AP and PP, respec-
tively, which have not suffered any chemical alteration.
Accordingly, our results show that 30 of the studied wastes could
Fig. 3 (a) Effect of temperature on 30 of apple pomace and (b) moisture

16786 | RSC Adv., 2020, 10, 16783–16790
be estimated from available data in the literature of fresh fruits
and vegetables.

However, these predictive equations did not t the results of
SCG. Moreover, 30 showed an increasing tendency with
increasing M for SCG; these values were lower than the ones of
the other studied materials at the comparable M range (30–
60%). The presented food wastes had different origins. CW and
PP were only subjected to peeling; they still retained their
original composition. However, AP has been produced by
a pressing process, which has not altered the composition of the
peel but strongly affected the esh. In contrast, SCG originated
from an extraction process using water at an elevated temper-
ature that strongly affected the chemical composition of the
original material. Coffee is rich in bers, oil and water-soluble
components such as sugar. According to other studies, sugar
could not be detected in the chemical analysis of SCG as it is
commonly extracted through the coffee brewing process.24,25

However, the sugar content was found to be the most signicant
component to model dielectric properties in products such as
grapes or juices;26,27 thus, the absence of it in SCG could
diminish the dielectric constant values.

Results for SCG can be well described (correlation coefficient
of 0.998) with a second-order polynomial t (eqn (9)).

3
0
SCG ¼ 0.016M2 � 0.812M + 18.81 (9)

However, no literature was found on similar material at 2.45
GHz; results on parchment coffee have reported a third-order
polynomial t between 0.1–10 MHz for different moisture
contents.28
Effect of temperature on dielectric constant

In the case of CW, AP and PP, M dependent temperature effect
was observed on 30 values. Increasing T caused a linear change
(as an example, AP is shown in Fig. 3a), resulting in an increased
slope by decreasing the moisture content. The overall effect is
shown in Fig. 3b, where linear dependency was observed
(correlation coefficient ¼ 0.9346) irrespective of the type of
sample.

According to the correlation, M > 50.30% causes a decrease
in 30 with increasing T, and below this value 30 will increase with
the increase in T. The latter observation was found to be typical
for fresh fruits, vegetables13 and berries.29 Barba and d'Amore30
dependent slope of T(30) linear fit.

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Fig. 4 Temperature effect on the dielectric constant of spent coffee
grounds.

Fig. 5 Effect of the moisture content on the dielectric loss at room
temperature.

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described two phenomena corresponding to the temperature
effect on dielectric properties: (1) increment of 30 is expected as
bounded dipoles become more available to the orientation
effects of the electromagnetic eld at higher temperatures. (2) A
large amount of free water in the system solubilize sugar, starch
and mineral components, which enables the material to better
dissipate energy into heat at a higher temperature. Conse-
quently, a reductive effect on the energy storage and thus on the
dielectric constant can be observed. The combination of these
two effects in the material will determine the nal dielectric
behaviour under changing temperature.

In contrast to the former ndings, 30 of SCG did not show any
signicant change (P < 0.5) against increasing temperature (Fig. 4).
The composition of SCG ismostly limited to proteins, crude bers,
lignin, cellulose and lipids,24 thus having more similarity to agri-
cultural products, such as cereal grains with a low moisture
content. However, for such material, no general behaviour has
been found.31 According to Nelson, in the case of agricultural
products, the results depended on variety and moisture content.
Effect of moisture content on dielectric loss

The dielectric loss increased with moisture content until
a maximum level and then decreases at M > 50% in the case of
AP andM > 70% in the cases of CW and PP (Fig. 5). In the case of
SCG, 300 increased throughout the whole range. The highest
studied moisture content was the initial one of the waste
material. Therefore, no extrapolation should be made for
conditions over the studied moisture range.

The increasing tendency has been explained by the free water
content amount of the matrix in other studies.13,26,30,32 At low
moisture levels water correspondedmostly to the bounded form
(physically absorbed to the dry surface), showing a eld oscil-
lation. With the increment in water, critical moisture can be
achieved for molecules in the matrix, where the water is found
as a free form (found in capillaries) increasing the dielectric loss
of the matrix. The critical moisture content is matrix and
component-dependent, and in the present study, it was only
observed in the case of SCG between M ¼ 42% and 48%.
This journal is © The Royal Society of Chemistry 2020
When the dielectric loss of CW and PP reaches their
maximum, (Mz 70%) dissolved components (salts, sugars) are
at the saturation level. Higher moisture contents dilute the
solution, which leads to lower measured values.32 Due to the
saturation level of soluble compounds, increased 300 values were
expected and conrmed (Fig. 6a) with the increase in temper-
ature through higher solubilization of the components in the
case of CW.

Similar to the observed tendency for AP, the drying of red
delicious apples showed a rapid increase in 300 untilMz 50% and
slight increasing or even stable 300 values over that moisture.33

Comparing the waste materials, 300 values follow a tendency
of CW > PP > AP > SCG, which can be attributed to their different
chemical compositions. High ber (35–44%) and lipid (22–27%)
content24 of SCG maintain its 300 low. These components not
only express limited dipolar polarisation but also negatively
affect the availability of free water in the matrix.32 Moreover,
SCG disposed of low ash content of 1.3%,25 contributing to
a moderate loss factor.32

According to earlier reports,34–37 relations between ash
contents on the dry material basis of CW z 10%, PP z 4.5%
and AP z 2–3.5% follow the same tendency as their 300 values.
The observed effect of the ash content on the loss factor was
previously described for foods by38 referring to the increased
ionic component in the matrix.
Effect of temperature on dielectric loss

The temperature effect on the food matrix's loss factor can be
affected by several factors such as moisture content and chemical
composition. These factors have been reviewed in different
studies13,23,29,32,39 and the following conclusions have been drawn:
the presence of free water causes 300 to decrease with increasing
temperature, while at lower moisture levels, where bound water
content is signicant, and 300 will increase with temperature. In the
case of salt solutions, a double effect of the dipole and ionic loss
plays an important role. In the case of lower salt concentrations
(<1%) dipole loss dominates, resulting in a decrease in 300.
However, over a certain salt concentration, depending on the food
matrix, the dominating ionic loss leads to an increase in 300 at
RSC Adv., 2020, 10, 16783–16790 | 16787

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Fig. 6 Effect of temperature on dielectric loss for (a) carrot waste (CW), (b) apple pomace (AP), (c) pineapple peel (PP) and (d) spent coffee
grounds (SCG).

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higher temperatures. Sugar content will diminish the loss factor as
the temperature rises.

The studied matrices here, showed different behavior with
increasing temperature (Fig. 6a–d). The dielectric loss of CW
(Fig. 6a) at M1 (90.4%) was lower than at M2 (69.4%) at every
temperature. Moreover, the dielectric loss of CW at M2 showed
an increasing tendency, probably due to the higher salt
concentration at M1. Previous studies evaluating the effect of
salt contents in rice samples showed that the dielectric loss
factor increased when salt was added.40

A clear tendency for 300 at M1 and M3 (64.6%) has not been
observed due to the equalizing effects of the components.
Results obtained at M4 (31.6%) slightly increased with temper-
ature, this time affected by the remained bound water content
in the carrot matrix.

In the case of PP (Fig. 6c) no clear tendencies have been
observed for M1, M2, and M3. Nevertheless, the material at M2

(61.04%), related to higher ionic loss and still signicant free
water content increased with temperature.

The origin of AP and SCG are different from the other
materials, as discussed in a former section. Due to the pro-
cessing, their soluble fraction was lower and therefore cannot
contribute signicantly to the dielectric loss. Slightly decreasing
300 have been measured for AP (Fig. 6b) as well as for SCG
(Fig. 6d) at M1 (58.2%). The dielectric loss of SCG remained
mostly unaffected by temperature due to the synergic effect of
bound water and considerable oil content.32
Effect of moisture content and temperature on penetration
depth

The calculated penetration depth of CW, AP, PP and SCG
showed dispersed behaviour as affected by temperature and
16788 | RSC Adv., 2020, 10, 16783–16790
moisture content (Fig. 7). It was expected from other studies41–43

that at lower moisture levels higher penetration depth can be
reached as the high dielectric constant of water responsible for
the energy absorption at the surface. However, the effect of
temperature was diverse in those studies and depended on the
food moisture content. In the case of carrot peel (Fig. 7a) and
pineapple peel (Fig. 7c) dp decreased at all moisture levels when
the temperature increases. Similar behaviour was observed for
rice bran,41 pistachios,42 potato starch and apple at lowmoisture
contents.42 Both waste products showed an initial decrease in dp
when moisture content decreased; however, at M lower than
69%, an increase in dp was observed. This may have occurred
due to observation of the maximum values of 300 in the case of
CW and PP (Fig. 5), and can be connected to the saturation level
of dissolved components.

The results of apple pomace (Fig. 7b) and spent coffee
grounds (Fig. 7d) dp showed an increasing trend of higher
temperatures, which was also observed for potato starch41 at
high moisture contents as well as for various fruits studied at
2.45 GHz.29,43 In case of the effect of the moisture content, the
behaviour of AP and SCG was contradictory: dp of AP decreased
with the decrease in M, while dp of SCG increased at lower
moisture contents. Latter behaviour was also described for
other food matrices.41,42,44

The presented values are of importance in order to under-
stand the power absorption of the food matrix and heat and
mass transfer during a microwave-assisted process.45 In order to
extract process-relevant data on penetration depth, the actual
porosity of the sample must be taken into account (eqn (6)) as
well as the dielectric properties of other materials involved,
such as solvents, e.g., in the case of extraction processes.
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https://doi.org/10.1039/c9ra10639a


Fig. 7 Power penetration depth at 2.45 GHz of (a) carrot waste, (b) apple pomace, (c) pineapple peel, (d) spent coffee grounds.

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Conclusions

Dielectric constant and loss of carrot waste, apple pomace, pine-
apple peel and spent coffee grounds were studied under different
temperatures and moisture content by open-ended coaxial cavity
at 2.45 GHz. The complex effect of the temperature, moisture and
effect of composition differences were observed on the results. The
moisture content (M) of the material was found to be critical: atM
< 50.3%, 30 increasedwith the increase in temperature, while above
this moisture level a decrease in 30 was observed.M < 60% showed
an increasing effect on 300, while 300 decreased at a higher moisture
content. Results were compared with literature data for carrot
waste and pineapple peel, where no composition changes may
have occurred through the waste generation. In contrast, apple
pomace and spent coffee grounds have shown different results
from that found in the literature. These differences also affected
the calculated penetration depth of the studied materials. Thus, it
was suggested that when considering food waste processing with
the microwave technology, the dielectric behaviour of fresh food
material should not be taken into account without considering
composition similarity between fresh food and food waste. The
emerging interest in food waste valorisation by the microwave
technology, such as extraction and drying processes, opens the
need for further studies on the dielectric properties of food waste.
Conflicts of interest

There are no conicts of interest to declare.
Acknowledgements

This project has received funding from the European Union's
Horizon 2020 research and innovation program under the
This journal is © The Royal Society of Chemistry 2020
Marie Sklodowska-Curie grant agreement No. 661198. Also, the
research stay of Pilar Rosales López was funded by Baden
Württemberg Foundation.
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	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products

	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products

	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products
	Effect of temperature and moisture contents on dielectric properties at 2.45 GHz of fruit and vegetable processing by-products