Food Biochemistry and Food Processing (2 edition)

(Steven Felgate) #1

BLBS102-c05 BLBS102-Simpson March 21, 2012 12:2 Trim: 276mm X 219mm Printer Name: Yet to Come


88 Part 1: Principles/Food Analysis

absorption intensities and regions of water vapor are different
from those of ozone, but both are responsible for UV absorption
in the atmosphere. Incidentally, both triatomic water and ozone
molecules are bent.

Hydrogen Bonding and Polymeric Water
in Vapor

Attraction between the lone pairs and hydrogen among water
molecules is much stronger than any dipole–dipole interac-
tions. This type of attraction is known as the hydrogen bond
(O H O), a very prominent feature of water. Hydrogen bonds
are directional and are more like covalent bonds than strong
dipole–dipole interactions. Each water molecule has the capac-
ity to form four hydrogen bonds, two by donating its own H
atoms and two by accepting H atoms from other molecules. In
the structure of ice, to be described later, all water molecules,
except those on the surface, have four hydrogen bonds.
Attractions and strong hydrogen bonds among molecules form
water dimersand polymericwater clustersin water vapor. Mi-
crowave spectroscopy has revealed their existence in the atmo-
sphere (Goldman et al. 2001, Huisken et al. 1996).
As water dimers collide with other water molecules, trimer
and higher polymers form. The directional nature of the hydro-
gen bond led to the belief that water clusters are linear, ring,
or cage-like rather than aggregates of molecules in clusters
(see Fig. 5.4). Water dimers, chains, and rings have one and
two hydrogen-bonded neighbors. There are three neighbors per
molecule in cage-like polymers. Because molecules are free to
move in the gas and liquid state, the number of nearest neigh-

bors is between four and six. Thus, water dimers and clusters are
entities between water vapor and condensed water (Bjorneholm
et al. 1999).
By analogy, when a few water molecules are intimately as-
sociated with biomolecules and food molecules, their properties
would be similar to those of clusters.

CONDENSED WATER PHASES


Below the critical temperature of 647 K (374◦C) and under
the proper pressure, water molecules condense to form a liq-
uid or solid—condensed water. Properties of water, ice, and
vapor must be considered in freezing, pressure-cooking, and
microwave heating. In food processing, these phases transform
among one another. The transitions and the properties of con-
densed phases are manifestations of microscopic properties of
water molecules. However, condensation modifies microscopic
properties such as bond lengths, bond angles, vibration, rota-
tion, and electronic energy levels. The same is true when water
molecules interact with biomolecules and food molecules. All
phases of water play important parts in biochemistry and food
science.
Water has many anomalous properties, which are related to
polarity and hydrogen bonding. The melting point (mp), boil-
ing point (bp), and critical temperature are abnormally high for
water. As a rule, the melting and boiling points of a substance
are related to its molecular mass; the higher the molar mass, the
higher the mp and bp. Mp and bp of water (molar mass 18, mp
273 K, bp 373 K) are higher than those of hydrogen compounds
of adjacent elements of the same period, NH 3 (molar mass 17,

Figure 5.4.Hydrogen bonding in water dimers and cyclic forms of trimer and tetramer. Linear and transitional forms are also possible for
trimers, tetramers, and polymers.
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