Investigation Rheological Behavior of Chocolate

Ioana Stanciu*

University of Bucharest, Faculty of Chemistry, Department of Physical Chemistry, Elisabeta Blvd, Bucharest, Romania.

Corresponding Author E-mail: istanciu75@yahoo.com

Article Publishing History
Article Received on : 13 Jun 2024
Article Accepted on :
Article Published : 06 Aug 2024

ABSTRACT:

In this article we studied chocolate with 100% cocoa without lecithin and traces of milk in the form of chips. The data obtained are in accordance with those obtained from the specialized literature. This article proposes two relations of dependence of log dynamic viscosity on log shear rate. The relations determined by second-order polynomial and exponential fitting can be successfully applied to confectionery products because the obtained correlation coefficients are close to unity.

KEYWORDS:

Chocolate; Investigation; Rheological; Viscosity

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Stanciu I. Investigation Rheological Behavior of Chocolate. Orient J Chem 2024;40(4).

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Stanciu I. Investigation Rheological Behavior of Chocolate. Orient J Chem 2024;40(4). Available from: https://bit.ly/4fMHyGr

Introduction

Chocolate was discovered in the years 250-290 after Christ in Central America.

Although it is possible that other explorers had discovered chocolate in America long before, Europeans did not learn about this delicious drink until 1521. Chocolate even became a reason for war with the arrival of the Spanish conquistadors on April 21, 1519, led by their leader Hernán Cortés that allows access to the sources of the use of cocoa powder: the Aztec king believed that he was dealing with the god Montezuma, whose return was predicted by legends for this very day and he welcomed the conquistadors by offering them to drink from a cup of gold, a bitter drink “Xocoatl” with refreshing virtues. Hernán Cortés imposed this drink on his army, noting that “one cup of this precious drink lasts the people for a whole day’s march, without the need for other food” [1-9].

The first Colombian chroniclers tell that the drink consisted of a liquid in which crushed cocoa beans, carob powder, vanilla, whole cloves, hazelnuts, almonds, pistachios, orange blossom and rose water, pepper powder, hot peppers were mixed. , cinnamon and corn puree. Everything was connected by successively pouring the drink from one container to another, then by repeated mixing, which produced a lot of foam. Later, honey, musk and amber are added to suppress the bitterness of the mixture.

Hernán Cortés decided to bring the famous seeds with him, along with other treasures, on his return to Spain. The first load of cocoa leaves with a “vento chocolatero”, the name given in Mexico to the northern breezes that favored navigation. The Italian poet Pietro Andrea Forzoni summarized its virtues: “A sweet ambrosia, source of health, spiritual support of a life full of weakness, so coveted by the immortal inhabitants of the celestial heights!”. From the tonic to the aphrodisiac, it was only one step, easily surpassed by the historian Bernard Diaz. According to him, Emperor Montezuma used to drink a cup of the precious elixir before crossing the threshold of his harem. Even Casanova and the Marquis de Sade did not forget this elixir.

Chocolate is a special group of sugary products made from cocoa beans, sugar, milk, hazelnuts, nuts. It is distinguished by a particularly fine and pleasant taste and aroma. Chocolate has a higher nutritional value (500-600 calories per 100g) than other sugary products whose value is between 300-400-500 calories per 100g. In addition to the fatty substances, carbohydrates and proteins that constitute the basis of food, chocolate also contains small amounts of theobromine, caffeine, organic acids, among which the oxalic one is in greater quantity, tanning substances, pigments, essential oils, lecithin, substances minerals [9-13].

Basic raw materials and auxiliary materials are used in the manufacture of sugary products (chocolate). So:

a) The basic raw materials are: sugar, glucose, invert sugar (a mixture of equal parts of glucose and fructose), used for the total or partial replacement of glucose, powdered milk, concentrated milk (used to obtain milk candies and caramels) , fats (cow butter, cocoa butter, margarine).

b) Auxiliary raw materials are the following: starch, fruit (in the form of jams or pastes for fillings, in the form of candied fruit, fruit in alcohol), fatty kernels of some fruits (walnut kernels, hazelnuts, apricots, peanuts), seeds oleaginous (sunflower, sesame) used to obtain halvah, lecithin (used in the manufacture of chocolate, as an emulsifier), agar-agar (gelling substance extracted from certain seaweeds, used to obtain jellies), food acids (citric, tartaric ), flavors (natural and synthetic) used for flavoring sugary products [13-20].

Material and methods

In this article we studied pure chocolate with 100% cocoa without lecithin or traces of milk in the form of chocolate chips. The chocolate was heated in a water bath with a TC-650 type thermostat and the viscosity was determined with the DV-3P rotary viscometer.

Results and discussion

Figures 1-5 represent linearization of  rheograms of chocolate samples in the range of temperatures at which they were studied.

By linearizing the rheograms at a temperature of 36 degrees Celsius, a second-order exponential equation is obtained with the parameters A, B, C, D and the correlation coefficients r2:

η = 0 +Aexp(-log γ /-B) – Cexp(log  γ0/-D)  (1)

The parameters of the formula by η = 0 +Aexp(-log γ /-B) – Cexp(log  γ0/-D) are given in table 1.  

Table 1: Parameters formula η = 0 +Aexp(-log γ /-B) – Cexp(log  γ0/-D)

Temperature,

°C

Parameters formula η = 0 +Aexp(-log γ /-B) – Cexp(log  γ0/-D)

r2

 

A

B

C

D

36

0

8.97702

-6.90885

-7.79546

-6.77266E98

0.99998

38

0

8.01267

-6.26559

-6.86225

-8.13906E128

0.99997

40

0

7.97132

-6.25213

-6.83903

-6.01613E126

0.99996

42

0

8.10352

-6.36933

-6.98847

-7.98198E125

0.99995

44

0

8.40778

-6.61737

-7.30339

-3.64452E132

0.99992

 

By linearizing the rheograms at a temperature of 36 degrees Celsius, a polynomial formula is obtained with the parameters A, B and C and the correlation coefficients r2 [13]:

log η = A + Blog γ + C log γ2                              (2)

The parameters of the formula log η = A + Blog γ + C log γ2 are given in table 2.

Table 2: Parameters formula  log η = A + Blog γ + C log γ2

Temperature,

°C

Parameters formula log η = A + Blog γ + C log γ2

r2

A

B

C

36

1.18027

1.30368

0.09853

0.99996

38

1.14892

1.28409

0.1074

0.99994

40

1.1303

1.28027

0.10845

0.99992

42

1.1132

1.27747

0.10598

0.99991

44

1.10281

1.27560

0.10138

0.99988

 

Conclusions

Chocolate has a non-Newtonian behavior in the temperature range in which it was studied.. The two equations that describe the rheological behavior of chocolate have correlation coefficients close to unity. In this article we studied chocolate with 100% cocoa without lecithin and traces of milk in the form of chips. The data obtained are in accordance with those obtained from the specialized literature.

Acknowledgement

The author would like to thank, (Insert university name and Dept. name) for their guidance and support to complete this article.

Conflict of Interest

The authors do not have any conflict of interest.

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