That sounds like a great way to rule over people o_O
Hydrogen sulfide (formula: ) is a chemical compound which occurs as a colourless gas with acidic properties. Its characteristic odor, which resembles that of rotten eggs makes the identification of the compound easy.
It is present in the atmosphere (in low concetrations, less than 0.0003ppm) and also works as a signaling molecule for many animals, including humans. Its odor can be identified at concentrations of around 0.1 to 0.15ppm. As the concentration increases, it obtains a sweet odor and becomes deadly.
It's corrosive and flammable.

Boiling PointAcidity (pKa)
-60.2 Celcius7.0
One should not forget that our bodies can produce hydrogen sulfide with the help of speicifc bacteria found in our mouth and intestines.
These take advantage of the sulfur found in proteins that we consume (four aminoacids, the buldings blocks of proteins, contain sulfur).
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Sulfur that occurs as an unwanted compound in natural gas is also removed by hydrogenation, which yields hydrogen sulfide.
Created by the german chemist Carl Friedrich Claus, it makes it possible to convert hydrogen sulfide (from natural gas) to elemental sulfur.
The overall reaction can be descibed as follows:
The Claus' process served as a better replacement of the Frasch process, which obtained elemental sulfur from naturally found deposits underground.
Bleach refers to a wide range of chemical substances that are used mainly in order to whiten fabrics, clean surfaces and disinfect water supplies.
This range of substances works by oxidizing the molecules that either stain our clothes/furniture, or are part of unwanted germs. They can be divided into two main products:
  • Chlorine-based bleach: These function by releasing elemental chlorine. Elemental chloride on its own is also a form of bleach, although it is much more dangerous to handle.
  • Peroxide-based bleach: They release oxygen, which does the oxidation itself. Oxygen is derived from the decomposition of peroxide compounds (R-O-O-R).
White is often seen as a symbol of purity and virtue (even the ancient Egyptians and Greeks shared this view ), thus there was a need for effective fabric whitening methods.
Since the ancient times, people used a widely available "bleaching product", the sun itself (the small amounts of UV radiation that reach the surface of the earth, break up bonds of stain molecules that are responsible for the colours that we perceive).
Later in ancient rome, before the invention of soap, other alkaline products were used as cleaning agents, such as urine (which breaks down to ammonia). These only removed the grease stains from the cloth, before it was left to dry and whiten in the sun.
Ultimately, from wood ashes a better cleaning product was made which was lye. Lye is used as the main ingredient is soap making.
In the 17th century, the Dutch were leading the bleaching market. They invented a new method of bleaching which involved additions of bases and acid to the cloth. Firstly, the fabrics were soaked in lye in order to remove grease stains and then washed clean. Then they were spread out in specific places, called bleachfields. There, on the grass, they got whitened under the sun. This process was repeated several times. Lastly, sour milk was placed on the fabric in order to neutralize the bases added prior and once again a wash took place. This process was not only physically demanding, but also took months to finish.
Thankfully, after the discovery of elemental Chlorine by Karl Wilhelm Scheele, another scientist came up with a faster way to bleach clothes. He was Claude Berthollet, who made in 1789, what is known as "Eau de Javel" (commonly known as liquid bleach), which is a widely used bleach in laundry, cleaning and water treatment. That bleach consists of a solution of 3-6% NaClO.
Later, in 1798 Charles Tennant made a solution of known as bleaching powder. Peroxide-based bleach only became popular in the 20th century, after being made in a century ago.
Household bleach mainly contains sodium hypochloride, NaOCl (eau de Javel). It is an unstable white powder that dissolves in water to give a yellow stable solution.
It also contains small amounts of NaoH, and . The first method of producing bleach involved a reaction between chloride gas and sodium carbonate (). Later, sodium carbonate was replaced by caustic soda (soda lye), NaOH, a cheaper substance that also made the production more efficient.
In this reaction, is reaction with a solution of NaOH giving a spontaneous reaction:
The raw materials of the reaction, chloride and caustic soda come from the electrolysis of brine.
Starch is an organic structure (carbohydrate) composed of two distinct polymers, amylose and amylopectin that are all made up of repeated glucose molecules. It is used as a reserve of energy, providing plants with glucose molecules (and consequently energy) when photosynthesis can not occur (at night or in winter). In humans it's a source of glucose necessary for energy production. Starch is also used in papermaking, glue and laundry.
Starch is packed into semicrystalline granules (containing crystalline and non-crystalline section) called starch granules. These granules are either contained in plant leaves or stored for long term usage in the plant's seeds/roots/fruit. In the leaves, the starch granules are smaller and are located inside chloroplasts. This starch is termed transitory starch and is accessed during the night to provide the plant with energy. The granules contained in the plant's other organs hold starch referred to as storage starch which is reserved for long-term usage. These granules are stored inside special double-envelopped organelles called amyloplasts. Potato tubers contain this type of starch and are used as the potato plant's "battery" when the shoot of the plant has died and thus can not provide the plant with any energy (glucose) via photosynthesis.
The structure of starch granules has been debated and it's not yet clear. Nevertheless, scientists have identified some components. As the two polymers that make up starch are just repeated glucose molecules, starch consists only of glucose. Amylose is polymerized into a coiled chain of glucose molecules (no branching), while amylopectin shows a linear but branched structure. The granules consist of 10-30% amylose (percentage varies depending on source) and 70-90% amylopectin. The branched chains of amylopectin interact together and form double helices while the linear part of amylopectin that is not surrounded by its branches resides together with amylose chains. These amylose chains form the amorphous (non-crystalline) part of the granules while the packed double helices form the crystalline one.
As starch is just a chain of glucose, , molecules (and is broken down by the enzyme amylase found in our saliva) it can provide an organism with its main source of energy through aerobic or anaerobic respitation. This process uses glycose with (aerobic) or without oxygen (anaerobic) to create ATP, the energy "currency" of organisms.
When we boil rice for example, we observe the grains swelling and becoming much more soft. This manifests itself in the process of starch gelatinization.
At high temperatures, the intermolecular bonds of the starch molecules (for example the double helices formed by amylopectin) are broken down (new water-starch hydrogen bonds are formed) and thus the structure of the starch granules is altered. First the amorphous regions are disrupted and then the granule's whole structure gets effected. The granules lose their integrity and burst. Amylose (and a smaller amount of amylopectin) molecules leave the granule and contribute to the increased viscosity of the liquid.
When the temperature drops, recrystallization occurs. This is referred to as starch retrogradation and is responsible for bread staling.
Glass is a state of matter, characterizing amorphous solids. The structure of glass neither exactly resembles that of a crystalline solid nor that of a liquid.
The properties of glass vary depending on its composition (over 400.000 types of glasses have been manufactuered) and thus it has big range of uses.
The most commonly used component of glass is silica, an element that is abundant in the Earth's crust (30% by mass). During the formation of our planet, rocks containing a high percentage of silica were melted and cooled rapidly under the hostile conditions of the environment (volcanic eruptions, lighting strikes), thus natural glass was made such as obsidian. Man-made glass was first produced about 4000 years ago and it was used mainly for jewellery. Then, glass couldn't be obtained in a pure/homogenous form and lacked transparency.
Glass continued to spread around the world and new techniques were invented but still, transparent glass could not be achieved until the middle ages.
This important step took place in the island of Murano. Cristallo was the first clear, colourless, transparent glass and was made by the Venetian glass blower Cesaro Barovier in the 15th century.
Another marking point in the glassmaking industry was the invention of crown glass, which was a simpler process that prevailed in the middle ages. The glass that was manufactured by this method is sometimes thicker in the bottom than at the top. That is not attributed to the viscosity of the glass (a common misconception) but rather to the glass making process itself. It was slowly replaced in the 19th century by cylinder blown sheet glass, another hand-blown technique.
It took many years for man to study the relation of glass composition and properties. The industry only saw very steep scientific progress in the 19th century.
After we became aware of the underlying science of the craft, the glass making process was automated and improved to accomondate all our needs. The mass production of glass objects is done with the help of machines that create the desired shapes of the products using moulds.
A common misconsception suggests that glass is a liquid of high viscosity. This not the case. Glass is its own distinct state of matter that doesn't coincide with any other classical one. Every liquid (except Helium) can be turned into glass, if a sufficiently rapid cooling takes place. This process is called vitrification. When a liquid is cooled (water for example) it normally goes through the process of crystallization. We say that the water is frozen as ice forms which has a very specific structure that is characterized by its stability (crystalline solid). If the cooling happens quickly enough, the water molecules don't have the opportunity to occupy the lowest energy sites and this is how the amorphous solids forms.
Annealing illustrates this phenomenon. When glass is cooled down in order to solidify, this process must be done during a specific time interval in order for the molecules to have enough time to position themselves in a more stable manner. If during the glass making process, the produced glass has been solidified too rapidly, then the stress present in the solid makes it too fragile to the point where it can rupture/shatter even during handling. By reheating the glass and slowly droping the temperature again, we ensure that the glass object has gained a much more stable structure.
As crystalline solids have a melting point, amorphous ones have a glass transition temperature which surprisingly depends on thermal history (how rapidly was the former liquid made into glass?). Around this temperature point, the viscosity of the glass increases rapidly and can be classified as a solid (under classical terms). It should be noted that the viscosity as well as other properties of the substance made into glass, present a continuous change as the temperature changes. This is not the case with "ordinary" freezing as liquid water turns spontaneously into a solid in a discontinuous manner (during the freezing process the temperature stays constant. Immediately below all the water has turned into ice).
The glass state is metastable and its transition to a crystalline solid is thermodynamically favoured although kinetically inert.
The works of Zachariasen and Warren (Network Theory and its verification by X-ray diffraction) resulted in big advancements in the study of glass structure. This theory can predict a large number properties of conventional glasses. His theory was later extended by Dietzel.
Zachariasen presented three types of cations that form a glass:
  • Network-formers that have a high oxidation state with a coordination number (number of bonds they form) generally of 3 or 4 (for example: Si, B, P, Ge, As, Be). These are connected together with the help of anions present in the glass.
  • Network-modifiers that are placed in order to disrupt the organized structure of the network. As they are cations they place themselves close to the anions (oxygen in for example) that connects the network. They break some bridging covalent bonds and "stick" to the broken ends electrostatically forming ionic bonds of lower energy. This reduces the viscosity so that the glass can be manufactured more efficiently, as it softens in a lower temperature.
  • Intermediates which assist in glass formation by forming intermediate bonds to oxygen. They can't form glasses on their own.
In order for glass to form, the network-former should (although there are exceptions) form polyhedral groups in its simplest form. (For example silica, forms tetrahedrals). Each polyhedron should only connect with its neighbouring once via bonding bridges formed by the anions (in this example an Si-O-Si).
The network-former of silicate glass is which is
This type of glass accounts for 90% of commercially used glass. Its uses range from windows to even jars. It is typically made of (w/w) 70% silica (), 10% lime () and 15% soda ().
Silica is the network-former of the glass. Silica, is found in nature as quartz and its pure form is the ideal glass. Nevertheless, soda is added in order to reduce the temperature at which the glass is softened, thus making its production cheaper and better to work with. Since sodium cations are very soluble in water, lime is added in order to decrease the solubility of the glass.
Silica is obtained by sand and mixed with soda ash () and limestone (). These materials are mixed together to get a powder called batch which is later combined with cullet (recycled glass pieces) in order for the glass to once again soften at even lower temperatures. The mix is heated into an oven at temperatures around . Impurities that arise are removed and the melted mass is put into moulds to take its final shape. Annealing is also taking place at the end to ensure glass durability, which is the process of reheated the bottle and then slowly cooling it down in order to further stabilize the structure of the glass.
Soda lime glass is recyclable.
The Sun's rays are not monochromatic and represent photons of various wavelength that may or may not be part of the visible light. In glass, some ions absorb particular wavelengths in the visible light and emit only the remaining wavelength. This is what contitutes the colour of an object. If an ion absorbs photons of red light, it appears bluish. These ions are normally transition metals as they can absorb photons of wavelengths that we can see.
The colour that we perceive by the glass is not only related to the ions contained in the glass but it also depends on the network-former/modifiers present. This is because the ions interact with them, which influences each ion's orbital energy levels and consequently the light that they can absorb. Lastly the colour also depends on the concentration of the ion, its nature (valency) and the heterogeneity of the glass. A portion of the light that arrives in the surface of the glass gets reflected and doesn't interact further.
A list summarizing some generally perceived colours and their associated ions:
  • () yellow-brown
  • () blue
  • () blue
  • () red
  • () green
  • () yellow
  • () green
  • () yellow
  • () violet
Glasses can also be coloured by metal colloids or to coloured particles.
Glass Chemistry by Werner Vogel (1994)

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