Chapter 2: Alternative Organic Solvents PDF

Summary

This chapter explores alternative organic solvents and their applications in green chemistry. It discusses the importance of energy efficiency in chemical reactions and explores methods such as using microwaves and sonochemistry to enhance reaction rates. The chapter also examines the role of electrochemistry and photochemical reactions in achieving more sustainable chemical processes.

Full Transcript

CH2
Alternative Organic
Solvents/Energy Efficiency.
Dr.Waseem Abu Oun
 Alternative Organic Solvents
OBJECTI
VES
Alternative Organic Solvents
Alternative Organic Solvents
Alternative Organic Solvents
Alternative Organic Solvents
Solvents Effects and Green Chemistry
Green Solvents & Its Defintions
Green Solvents & Its Defintions
Green Solvents in Green Chemistry
Specific Health & Environmental Requirement
Specific Health & Environmental Requirement
Specific Health & Environmental Requirement
Green Solvents for Academic Chemistry
Green Solvents for Academic Chemistry
Chemical Properties of Solvents
Chemical Properties of Solvents
Energy Efficiency
 Energy Efficiency
One of the most important aspects of
green chemistry is the enhancement of
the speed and degree of completion of
chemical reactions. One of the ways that
this is done is by lowering the activation
energy required to enable a reaction to
proceed. That is what catalysts do as
discussed in the preceding section. The
other way to enhance a reaction is by
adding energy as discussed in this
section.
 Energy Efficiency

Figure 13.7. Action of an iron-containing compound modeled after iron-based enzymes as a catalyst to bring about the oxidation of an alkene hydrocarbon group with
hydrogen peroxide

The most straightforward means to add energy to a reaction is by heating the reaction mixture.
On an industrial scale this is commonly accomplished with coils of tubing immersed in the reaction mixture that are heated with
steam passing through the coils. Heating by passing a current of electricity through electrically-resistant coils is also a means of
adding energy to a chemical system.
Much of the effort in green chemistry has been devoted to finding more sophisticated ways of energizing chemical systems.
Energy Efficiency
Need To Design Energy Efficiency
 Energy Efficiency

3.ELECTROCHEMISTRY
4.PHOTOCHEMICAL
REACTION
Microwaves can be used to add energy to reactions to enhance reaction rates.
Microwaves are electromagnetic radiation with wavelengths of 1 cm to 1 m
(frequency 30 GHz to 300 Hz). To avoid interference with microwave bands used in
communication, industrial and household microwave generators commonly operate at
2.45 GHz.
Microwaves are absorbed by polar molecules, such as those of water, causing rapidly
repeating re-orientation of the molecules in a microwave field.
The result is a high input of energy directly into substances subjected to microwaves
thereby adding energy and speeding up reactions. Microwave energy can be put
directly into relatively small volumes of reaction media, reducing material
requirements and minimizing wastes.
Microwaves can be used to enhance reactions in
water media.
(2) polar organic solvents such as dimethylformamide.
(3) media-free reactions, such as mixed solid reactants.
Sonochemistry adds energy by subjecting a reaction medium to ultrasound
energy at frequencies between 20 and 100 KHz which introduces very high energy
pulses into the medium. Commonly, the ultrasound is produced by the piezoelectric
effect through which crystals of substances such as ceramic-impregnated barium
titanate are subjected to rapidly reversing electrical fields converting the electrical
energy to sound energy with an efficiency that can reach 95%. An advantage of
sonochemistry is that it can introduce high energy into microscopic regions
enabling reactions to occur without appreciably heating the reaction medium.
 Electrochemistry
by the passage of a direct current of electricity through a reaction medium can
cause both reductions and oxidations to occur. Reduction, the addition of
electrons, e-, occurs at the relatively negatively charged cathode, and oxidation,
the loss of electrons, at the relatively positively charged anode. Electrochemical
oxidation and reduction can be controlled by the electrical potentials applied, by
the media in which they occur, and by the electrodes used. Because the addition
of electrons to the reaction medium (reduction) and their accompanying
removal (oxidation) does not add matter, electrolytic syntheses meet the goals
of green chemistry. The electrolytic production of oxygen and of hydrogen, a
non-polluting fuel and valuable raw material.
 Photochemical reactions
use the energy of photons of light or ultraviolet radiation to cause reactions to occur. The energy, E, of a photon of
electromagnetic radiation of frequency,ν, is E =hν, where h is Planck’s constant. Since a photon can be absorbed directly by a
molecule or a functional group on a molecule, the application of electromagnetic radiation of the appropriate energy to a
reaction medium can introduce a high amount of energy into a reactant species without significantly heating the medium.
Photochemical energy can be used to cause synthesis reactions to occur more efficiently and with less production of waste
byproducts than nonphotochemical processes. One example is the acylation of benzoquinone with an aldehyde to produce an
acyl hydroquinone, an intermediate used to make some specialty polymers: