Extracting Limonene from orange peel

Lily Yang 402

Limonene
A colourless, unsaturated hydrocarbon. Volatile liquid at room temperature and pressure, with a boiling point of 176 degree Celsius.


Molecular structure of limonene. It is a cyclic monoterpene, containing two isoprene units and having the formula C₁₀H_16. 

Limonene is chiral, meaning the enantiomers cannot be superimposed on its mirror image. It occurs naturally as the R enantiomer.

There are two isomers of limonene: D-limonene and L-limonene.
D-limonene has a citrus smell. It occurs in citrus peels such as orange.
L-limonene smells like turpentine and pine. It can be found in pines, conifers, as well as herbs like mint.

Why extract D-Limonene?
D-limonene is an essential oil. Essential oils have important functions in plants, repelling fungi and pests. The sweet fragrances of flowers attract pollinators. In fruits, essential oils attract fruit-eating animals that help to disperse the seeds.

+ fruit peels like orange and lemon are discarded after consumption. Extracting limonene is green because the peels are reused :)
+ combustable, thus can be used as a potential renewable biofuel
+ important medicinal properties: sedative, anti-stress, anti-carcinogenic, relieves heartburn and gastrointestinal reflux
+ useful in chemical synthesis: a precursor to carvone
+ solvent for cleaning products
+ used in cosmetic products, food flavorings and as a fragrance in the perfume industry
+ botanical insecticide, with fewer harmful side-effects compared to other insecticides such as DDT

How to extract D-Limonene?
Orange peel can be separated into two distinct layers: the pith and the skin.
The white pith contains negligible amount of orange oil, and is discarded.
The outer, orange part of the orange peel is the skin, and contains most of the orange oil.

Because  limonene is a relatively stable terpene, it can be extracted through steam distillation, without decomposing. This maintains the structure of the limonene molecules, crucial in ensuring the purity of limonene extracted.

Hot steam opens the pockets in orange peel, allowing volatile orange oil to be released. As the temperature increases, these volatile molecules vaporise and condense on the cooler surface of the condenser. Since limonene is volatile, it can vaporise at a temperature lower than its boiling point. Thus, the liquid collected from steam distillation is a mixture of water and limonene.


Cut the outer, orange part of the orange peel (skin)

Measure and record mass of orange peel in a pre-weighed container

Add distilled water and homogenise in a blender.

Transfer all of the mixture to a clean 250mL round bottom flask using filter funnel and spoon

Set up apparatus for fractional distillation. Turn on the hot plate and condenser water. Keep watch of the temperature of the vapour.

Collect distillate.

Immerse distillate in a water bath at 80°C. Allow liquid to settle; orange oil rises to the top.
Drain orange oil into a pre-weighed clean vial. Measure and record mass of orange oil for subsequent calculations.

Results
Initial mass of orange peel = 101.0g
Final mass of orange oil = 1.2g
% yield = 1.2g ÷ 101.0g x 100% = 1.19%

Due to the low volume of water added during homogenization, we extracted limonene with a higher purity, but obtained a lower yield.

The yield of limonene is quite high compared to other essential oils, which can range from 0.01-1%.

The presence of unsaturated hydrocarbons such as limonene can be tested by adding aqueous bromine to the orange oil. If mixture changes from brown to colourless, unsaturated hydrocarbons are present.

References
http://en.wikipedia.org/wiki/Limonene
http://www.catalysis-ed.org.uk/asymmetric/asymm1.htm
http://www.reading.ac.uk/web/FILES/chemistry/Limonene.pdf
https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgeEM2uxTs-X_XLQzRUGutaNYjR-qLUGPQn2pzdp3BANG4u5mLpnx9uv7zbVjpnAsDmAVcLfQ3MFusauJNHwaRXNNjHtJoKhyg7EqcbzB3OZjc7GM1DeY4zGv_J1to982OsZ10tj0UVaCA/s320/63793431JBJvJf_ph.jpg

Recycled paper

Lily Yang 402

Recycled paper
Paper can be made from substances containing fiber, such as wood pulp, rice or cotton. Paper recycling is turning waste paper into new paper products, including cardboard, toilet paper, etc.

Why is recycled paper useful?
+ produces less pollution than manufacturing virgin paper from trees, saves water :)
+ sustainable! Protects and conserves an important natural resource: forests. Forests are not only a source of wood, but also massive carbon sinks, playing a key role in recycling carbon in the carbon cycle. Photosynthesis by plants produces oxygen from carbon dioxide, and respiration produced carbon dioxide from oxygen
+ decreases the need for paper disposal. Saves landfill space and petroleum used in incineration plants
+ extends the paper fiber supply
+ paper is easier and requires less energy to recycle than aluminium or glass, because no heating is needed.

Fun fact!
Recycling 1 short ton (0.91 ton) of paper saves 17 mature trees, 7 thousand US gallons (26 m³) of water, 3 cubic yards (2.3 m³) of landfill space, 2 barrels of oil (320L), and 4100 kWh (15 GJ) of electricity – enough energy to power the average American home for six months :o

How to make recycled paper?
1. Blend newspaper with water in a blender
2. Pour the pulp into a tank, half-filled with water
3. Lift a frame into the tank to collect some pulp
4. Leave to dry overnight or use a hairdryer to dry
5. Carefully peel the paper from the frame

Taa Daa!!! Recycled paper is more rough and darker in colour than normal paper. However, it is good to write on :)

Let's look at how recycling paper is done on a large-scale!

Can paper be recycled forever?

When we make recycled paper, the blended pulp consisting of paper fibers and water is collected on the mold. After drying, only the paper fibers remain, forming recycled paper :)

As paper is recycled, fibers in the paper become weaker and shorter than virgin paper (produced from trees). This presents a limitation: paper cannot be recycled forever. Eventually, paper fibers become too weak, unable to stick together and  thus not feasible to recycle. This is why modern "recycled paper" contains a mixture of recycled fibers and virgin fibers, allowing paper to be recycled 5 to 7 times.
Recycled paper is also be less desirable for some purposes, such as photo-copying and printing paper.
Recycling paper is downstream cycling, or downcycling, in which the recycled product is cheaper and of lower quality than the original.





Fibers in wood pulp give paper its strength and structure
The individual fibers in this micrograph under UV light are around 10µm in diameter 

References
http://en.wikipedia.org/wiki/Paper_recycling
http://www.loveinfographics.com/categories/science-and-technology-infographics/how-paper-recycling-works-infographic-infographic
http://www.resourcetechnology.org/paper/videoFramesLrg/14-fibers-lg.jpg
http://www.handprint.com/HP/WCL/IMG/sheet.jpg
http://en.wikipedia.org/wiki/Paper

Green Chemistry and starch plastics

Lily Yang 402
What is Green Chemistry?
Green Chemistry encompasses three sectors: environment, economy and social equity.
Firstly, protecting our environment involves producing products that are reusable and recyclable.
Next, increasing efficiency of the chemical reaction is economical , saving costs for companies and individuals.
Most importantly, Green Chemistry ultimately aims to address mankind's concerns, welfare and to benefit people. I believe in Science for Humanity. There are many real-life applications of sustainable chemistry, which benefits people.


The solar bottle, made only using a bottle, water and bleach, lights up people's homes in Philippines.

12 Principles of Green Chemistry
Green chemists are guided by principles that aim to minimize harmful waste products, increase efficiency and safety, etc. We did a group activity to match examples to the corresponding principles. I was surprised that even simple things, like monitoring chemical reactions (at home too!), will make a great difference in reducing waste products and achieving the optimum reaction efficiency.
Explore the 12 principles here:
http://www.beyondbenign.org/greenchemistry/12principles.html

What are plastics?
Organic, mouldable polymers with high molecular mass.

Highly versatile and relatively cheap, used to make a range of products such as bottles, fabrics, food containers, etc.

Analysing problems with conventional plastic
- Petroleum is used: a finite, non-renewable natural resource, it will eventually be depleted quickly at the rate it is being used to synthesize conventional plastics
- High environmental footprint: releases large amounts of greenhouse gases, such as carbon dioxide
- Releases toxic wastes: contaminates the food chain, whereby toxic substances accumulate in larger predators (bioaccumulation) and eventually ends up in the human body.


Many polycarbonate water bottles contain BPA, an estrogen-like endocrine disruptor, which could cause hormone disorders and thus harm the body.
Both molecules contain two terminal hydroxyl groups and benzene ring.

- Difficult to decompose: ends up in landfills (land pollution), forests and oceans


Strong C-O bonds within the ester linkage are difficult to break, making conventional plastic difficult to decompose. Furthermore, polymer chains are entangled in a complex manner.

Marine life is endangered by plastic. Turtles mistake plastic bags for jellyfish (food), seals get caught in plastic, seabirds choke on bottle caps...

What is a solution to the problems of conventional plastic? Bioplastic!
Plastic that are compostable and made from renewable resources (eg. plant material).

Analysing pros and cons of bioplastic
+ Lowers environmental footprint: lowers greenhouse gas emission
+ Potential to be used as biofuel
+ Compostable, biodegradable by microbes to produce water, carbon dioxide and humus (nutrients for the soil, thus playing a key role in returning nutrients to the soil in the carbon cycle)


Cornware, bioplastic utensils made from corn, is biodegradable

- As costly as producing conventional plastic
- Bioplastic technology is not advanced yet
- Petroleum is used to generate electricity to power the production of bioplastic: petroleum still used :(
- Methane is released: 20 times more potent greenhouse gas than carbon dioxide, contributing to global warming
- Pesticides used to grow crops: lead to eutrophication, disruption of ecosystem and loss of biodiversity
- Plants are a source of food: people in less-developed countries suffer from hunger and malnutrition. Crops that can be used to feed starving people are used instead to produce bioplastic. This presents a moral controversy and dilemma

Corn starch/ potato starch plastics
Method
1. Mix corn oil, corn starch/ potato starch and a little water in a zip-loc bag
2. Microwave, leaving the zip seal open, for 25s
3. When the mixture has cooled, bioplastic is formed!

Potato starch plastic is smooth, more oily and flexible. This could be due to the higher amounts of corn oil added.
Corn starch plastic is less oily, brittle and hard.

The Chemistry behind. starch bioplastics..
Starch contains two chains of polymers: amylose and amylopectin.


Amylose is a linear molecule, giving the plastic its firmness. When starch is dried from an aqueous solution, it forms a film due to strong hydrogen bonds between the polymer chains.
Amylopectin is highly branched, giving the plastic undesirable softness and inhibiting the formation of film.

Acid hydrolysis:
By adding corn oil, fatty acids in the oil break down amylopectin. Unbranched amylose chains line up to form a stronger film. Vinegar can also be added, because the acetic acid present helps to break down amylopectin.

However, as the amylose chains are arranged too systematically, the film forms crystals and the starch bioplastic becomes brittle :( This is why the bioplastic formed was easily broken, unlike conventional plastic.

Improvements
Propane-1,2,3-triol/ glycerin acts as a plasticiser and can be added to prevent the brittleness of bioplastic. Because the plasticiser is hydroscopic, water molecules are attracted to it. Water prevents the film from becoming crystalline by entering the regions between the amylose chains. The bioplastic formed will be less strong, but more flexible and moldable. Plastic is more useful when flexible, as it can be molded into different shapes.

Plasticiser keeps the polymer chains further apart, disrupting the arrangement and weakening the forces of attraction between the chains.

References
http://www.philnews.ph/wp-content/uploads/2011/04/solar-bottle-light-bulb.jpg
http://www.phenoxy.com/images/plastics-composite.jpg
http://origin-ars.els-cdn.com/content/image/1-s2.0-S0018506X10002540-gr1.jpg
http://cool.conservation-us.org/jaic/img/jaic39-03-005-ch5fg2.jpg
http://cdn.coastalcare.org/wp-content/uploads/2009/11/plastic-pollution-seal-trapped.jpg
https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgt4zSGWnt69Q8pAxu6Y5dSchvNpz9dg_9P7OGCISU6hyreIjMQitB7hQS9DAl4gxWtvISOAFVTFdX3D9E69iAWY46pID-dWnAKfnfa1-Yd26IaOfg-hwnkvvPlWD7hsvFyw-kj4IsY0ilW/s200/bioplastic+fork+decomposing.jpg
http://thegreenmomreview.com/wp/wp-content/uploads/2009/06/5460_web.jpg
http://www.nuffieldfoundation.org/sites/default/files/images/potato-plastic-117.jpg
http://www.gcsescience.com/o59.htm