Organometallic compounds

Organometallic compounds are also known as organo-inorganics, metallo-organics and metalorganics. Organometallic compounds are distinguished by the prefix "organo-" e.g. organopalladium compounds. Examples of such organometallic compounds include all Gilman which contain lithium and copper. Tetracarbonyl nickel, and ferrocene are examples of organometallic compounds containing transition metals. Other examples include organomagnesium compounds like iodo(methyl)magnesium MeMgI, diethylmagnesium (Et₂Mg), and all Grignard reagents; organolithium compounds such as butyllithium (BuLi), organozinc compounds such as chloro(ethoxycarbonylmethyl)zinc (ClZnCH₂C(=O)OEt); and organocopper compounds such as lithium dimethylcuprate (Li⁺[CuMe₂]^–).

In addition to the traditional metals, lanthanides, actinides, and semimetals, elements such as boron, silicon, arsenic, and selenium are considered to form organometallic compounds, e.g. organoborane compounds such as triethylborane (Et₃B).

[ Coordination compounds with organic ligands

Many complexes feature coordination bonds between a metal and organic ligands. The organic ligands often bind the metal through a heteroatom such as oxygen or nitrogen, in which case such compounds are considered coordination compounds. However, if any of the ligands form a direct M-C bond, then complex is usually considered to be organometallic, e.g., [(C₆H₆)Ru(H₂O)₃]²⁺. Furthermore, many lipophilic compounds such as metal acetylacetonates and metal alkoxides are called "metalorganics."

Many organic coordination compounds occur naturally. For example, hemoglobin and myoglobin contain an iron center coordinated to the nitrogen atoms of a porphyrin ring; magnesium is the center of a chlorin ring in chlorophyll. The field of such inorganic compounds is known as bioinorganic chemistry. In contrast to these coordination compounds, methylcobalamin (a form of Vitamin B₁₂), with a cobalt-methyl bond, is a true organometallic complex, one of the few known in biology. This subset of complexes are often discussed within the subfield of bioorganometallic chemistry. Illustrative of the many functions of the B₁₂-dependent enzymes, the MTR enzyme catalyzes the transfer of a methyl group from a nitrogen on N5-methyl-tetrahydrofolate to the sulfur of homocysteine to produce methionine.

[ Structure and properties

The status of compounds in which the canonical anion has a delocalized structure in which the negative charge is shared with an atom more electronegative than carbon, as in enolates, may vary with the nature of the anionic moiety, the metal ion, and possibly the medium; in the absence of direct structural evidence for a carbon–metal bond, such compounds are not considered to be organometallic.

Depending mostly on the nature of metallic ion and somewhat on the nature of the organic compound, the character of the bond may either be ionic or covalent. Organic compounds bonded to sodium or potassium are primarily ionic. Those bonded to lead, tin, mercury, etc. are considered to have covalent bonds, and those bonded to magnesium or lithium have bonds with intermediate properties.

Organometallic compounds with bonds that have characters in between ionic and covalent are very important in industry, as they are both relatively stable in solutions and relatively ionic to undergo reactions. Two important classes are organolithium and Grignard reagents. In certain organometallic compounds such as ferrocene or dibenzenechromium, the pi orbitals of the organic moiety ligate the metal.

[ Applications

Organometallics find practical uses as stoichiometric and catalytically active compounds. Tetraethyl lead previously was combined with gasoline as an antiknock agent. Due to lead"s toxicity it is no longer used, its replacements being other organometallic compounds such as ferrocene and methylcyclopentadienyl manganese tricarbonyl (MMT). The Monsanto process utilizes a rhodium-carbonyl complex to manufacture acetic acid from methanol and carbon monoxide industrially. Similarly, the Wacker process is used in the oxidation of Olefins. The Ziegler-Natta catalyst is a titanium-based organometallic compound used in the production of polyethylene and other polymers.

Ryoji Noyori"s chiral ruthenium-BINAP complex catalytically reduces beta-ketoesters to secondary alcohols in the production of fine chemicals and pharmaceuticals. Another common industrial organometallic compound is the Grubbs catalyst, a carbenoid (an organometallic compound of a carbene and a metal).

Organometallic compounds of the reactive metals such as lithium or zinc are extremely basic and may also act as reductants. These superbases are used in organic syntheses. Butyllithium is an example, widely used in synthetic organic chemistry. They are air-sensitive, however, and their flammability severely limits their industrial use.

[ Concepts

Electron counting is key in understanding organometallic chemistry. The 18-electron rule is helpful in predicting the stabilities of organometallic compounds. Organometallic compounds which have 18 electrons (filled s, p, and penultimate d orbitals) are relatively stable. This suggests the compound is isolable, but it can result in the compound being inert.

To understand chemical bonding and reactivity in organometallic compounds the isolobal principle should be used. NMR and infrared spectroscopy are common techniques used to determine structure and bonding in this field. Scientists are allowed to probe fluxional behaviors of compounds with variable-temperature NMR.

Organometallic compounds undergo several important reactions:

• oxidative addition and reductive elimination
• transmetalation
• carbometalation
• Hydrometalation
• electron transfer
• beta-hydride elimination
• organometallic substitution reaction
• carbon-hydrogen bond activation
• cyclometalation

[edit]

Effects on humans

Main article: Short-term effects of alcohol

The National Institute on Alcohol Abuse and Alcoholism maintains a database of alcohol-related health effects. ^[81]

BAC (mg/dL)	Symptoms[82]
50	Euphoria, talkativeness, relaxation
100	Central nervous system depression, impaired motor and sensory function, impaired cognition
>140	Decreased blood flow to brain
300	Stupefaction, possible unconsciousness
400	Possible death
>550	Death

[ Effects on the central nervous system

Ethanol is a central nervous system depressant and has significant psychoactive effects in sublethal doses; for specifics, see effects of alcohol on the body by dose. Based on its abilities to change the human consciousness, ethanol is considered a drug.^[83] Death from ethyl alcohol consumption is possible when blood alcohol level reaches 0.4%. A blood level of 0.5% or more is commonly fatal. Levels of even less than 0.1% can cause intoxication, with unconsciousness often occurring at 0.3–0.4%.^[84]

The amount of ethanol in the body is typically quantified by blood alcohol content (BAC), the milligrams of ethanol per 100 milliliters of blood. The table at right summarizes the symptoms of ethanol consumption. Small doses of ethanol generally produce euphoria and relaxation; people experiencing these symptoms tend to become talkative and less inhibited, and may exhibit poor judgment. At higher dosages (BAC > 100 mg/dl), ethanol acts as a central nervous system depressant, producing at progressively higher dosages, impaired sensory and motor function, slowed cognition, stupefaction, unconsciousness, and possible death.

In America, about half of the deaths in car accidents occur in alcohol-related crashes.^[85] There is no completely-safe level of alcohol for driving; the risk of a fatal car accident rises with the level of alcohol in the driver"s blood.^[86] However, most drunk driving laws governing the acceptable levels in the blood while driving or operating heavy machinery set typical upper limits of blood alcohol content (BAC) between 0.05% to 0.08%.

[ Effects on metabolism

Main article: Alcohol metabolism

Ethanol within the human body is converted into acetaldehyde by alcohol dehydrogenase and then into acetic acid by acetaldehyde dehydrogenase. The product of the first step of this breakdown, acetaldehyde,^[87] is more toxic than ethanol. Acetaldehyde is linked to most of the clinical effects of alcohol. It has been shown to increase the risk of developing cirrhosis of the liver,^[77] multiple forms of cancer, and alcoholism.

[ Drug interactions

Ethanol can intesify the sedation caused by other central nervous system depressant drugs such as barbiturates, benzodiazepines, opioids, and phenothiazines^[84]

[ Magnitude of effects

Some individuals have less-effective forms of one or both of the metabolizing enzymes, and can experience more-severe symptoms from ethanol consumption than others. Conversely, those who have acquired alcohol tolerance have a greater quantity of these enzymes, and metabolize ethanol more rapidly.^[88]

[Birth defects

Ethanol is classified as a teratogen. See fetal alcohol syndrome.

[ Other effects

Frequent drinking of alcoholic beverages has been shown to be a major contributing factor in cases of elevated blood levels of triglycerides.^[89]

Ethanol is not a carcinogen.^[90][91] However, the first metabolic product of ethanol, acetaldehyde, is toxic, mutagenic, and carcinogenic. Also, ethanol"s effect on the liver can contribute to immune suppression. Consequently, consumption of alcoholic beverages can be an aggravating factor in carcinogenesis.

. 

[ Food versus fuel debate

Further information: Food vs fuel

It is disputed whether corn ethanol as an automotive fuel results in a net energy gain or loss. As reported in "The Energy Balance of Corn Ethanol: an Update,"^[48] the energy returned on energy invested (EROEI) for ethanol made from corn in the U.S. is 1.34 (it yields 34% more energy than it takes to produce it). Input energy includes natural gas based fertilizers, farm equipment, transformation from corn or other materials, and transportation. However, other researchers report that the production of ethanol consumes more energy than it yields.^[49][50] In comparison, sugar cane ethanol EROEI is at around 8 (it yields 8 joules for each joule used to produce it).^{[citation needed]} Recent research suggests that cellulosic crops such as switchgrass provide a much better net energy production than corn, producing over five times as much energy as the total used to produce the crop and convert it to fuel.^[51] If this research is confirmed, cellulosic crops will most likely displace corn as the main fuel crop for producing bioethanol.

Michael Grunwald reports that one person could be fed 365 days "on the corn needed to fill an ethanol-fueled SUV".^[52] He further reports that though "hyped as an eco-friendly fuel, ethanol increases global warming, destroys forests and inflates food prices." Environmentalists, livestock farmers, and opponents of subsidies say that increased ethanol production won"t meet energy goals and may damage the environment, while at the same time causing worldwide food prices to soar. Some of the controversial subsidies in the past have included more than $10 billion to Archer-Daniels-Midland since 1980.^{[53][neutrality disputed]} Critics also speculate that as ethanol is more widely used, changing irrigation practices could greatly increase pressure on water resources. In October 2007, 28 environmental groups decried the Renewable Fuels Standard (RFS), a legislative effort intended to increase ethanol production, and said that the measure will "lead to substantial environmental damage and a system of biofuels production that will not benefit family farmers...will not promote sustainable agriculture and will not mitigate global climate change."^[54][55]

Recent articles have also blamed subsidized ethanol production for the nearly 200% increase in milk prices since 2004,^[56] although that is disputed by some^{[citation needed]}. Especially since the price of fuel has driven up the costs to cultivate, grow, harvest, ship, refine, bring to market, etc, all commodities including; but not limited to, milk. Not to mention the presence of speculators, and the recent growing interest in the commodities market by investors who have been scared away from a falling stock market.

Ethanol production uses the starch portion of corn, but the leftover protein can be used to create a high-nutrient, low-cost animal feed.^[57]

In 2007 the United Nations" independent expert on the right to food, called for a five-year moratorium on biofuel production from food crops, to allow time for development of non-food sources. He called recent increases in food costs because of fuel production, such as the quadrupling of world corn price in one year, a growing "catastrophe" for the poor.^[58] In February 2007, riots occurred in Mexico because of the skyrocketing price of tortillas. Ethanol has been credited as the reason for this increase in food prices^[59]. The demand for corn has had a rippling effect on many corn-based products, like tortillas. The effects of ethanol and the increasing cost of food have also been felt in Pakistan, Indonesia, and Egypt.^[60]

Oil has historically had a much higher EROEI than corn produced ethanol, according to some^{[citation needed]}. However, oil must be refined into gasoline before it can be used for automobile fuel. Refining, as well as exploration and drilling, consumes energy. The difference between the energy in the fuel (output energy) and the energy needed to produce it (input energy) is often expressed as a percent of the input energy and called net energy gain (or loss). Several studies released in 2002 estimated that the net energy gain for corn ethanol is between 21 and 34 percent. The net energy loss for MTBE is about 33 percent. When added to gasoline, ethanol can replace MTBE as an anti-knock agent without poisoning drinking water as MTBE does. In Brazil, where the broadest and longest ethanol producing experiment took place, improvements in agricultural practices and ethanol production improvements led to an increase in ethanol net energy gain from 300% to over 800% in recent years.^{[citation needed]} It must be noted that Brazil produces ethanol more efficiently because its primary input is the sugar from sugar cane rather than starches from corn. Consuming known oil reserves is increasing oil exploration and drilling energy consumption which is reducing oil EROEI (and energy balance) further.^[61]

Opponents claim that corn ethanol production does not result in a net energy gain or that the consequences of large scale ethanol production to the food industry and environment offset any potential gains from ethanol. It has been estimated that "if every bushel of U.S. corn, wheat, rice and soybean were used to produce ethanol, it would only cover about 4% of U.S. energy needs on a net basis."^[62] Many of the issues raised could likely be fixed by techniques now in development that produce ethanol from agricultural waste, such as paper waste, switchgrass, and other materials, but EIA Forecasts Significant Shortfall in Cellulosic Biofuel Production Compared to Target Set by Renewable Fuel Standard.^[63]

Proponents cite the potential gains to the U.S. economy both from domestic fuel production and increased demand for corn. Optimistic calculations project that the United States is capable of producing enough ethanol to completely replace gasoline consumption.^{[citation needed]} In comparison, Brazil"s ethanol consumption today covers more than 50% of all energy used by vehicles in that country.

In the United States, preferential regulatory and tax treatment of ethanol automotive fuels introduces complexities beyond its energy economics alone. North American automakers have in 2006 and 2007 promoted a blend of 85% ethanol and 15% gasoline, marketed as E85, and their flex-fuel vehicles, e.g. GM"s "Live Green, Go Yellow" campaign.^[64] The apparent motivation is the nature of U.S. Corporate Average Fuel Economy (CAFE) standards, which give an effective 54% fuel efficiency bonus to vehicles capable of running on 85% alcohol blends over vehicles not adapted to run on 85% alcohol blends.^[65] In addition to this auto manufacturer-driven impetus for 85% alcohol blends, the United States Environmental Protection Agency had authority to mandate that minimum proportions of oxygenates be added to automotive gasoline on regional and seasonal bases from 1992 until 2006 in an attempt to reduce air pollution, in particular ground-level ozone and smog.^[66] In the United States, incidents of methyl tert(iary)-butyl ether (MTBE) groundwater contamination have been recorded in the majority of the 50 states,^[67] and the State of California"s ban on the use of MTBE as a gasoline additive has further driven the more widespread use of ethanol as the most common fuel oxygenate.^[68]

A February 7, 2008 Associated Press article stated, "The widespread use of ethanol from corn could result in nearly twice the greenhouse gas emissions as the gasoline it would replace because of expected land-use changes, researchers concluded Thursday. The study challenges the rush to biofuels as a response to global warming."^[69]

One acre of land can yield about 7,110 pounds (3,225 kg) of corn, which can be processed into 328 gallons (1240.61 liters) of ethanol. That is about 26.1 pounds (11.84 kg) of corn per gallon.

Much overlooked in most discussions about ethanol from corn are the by-products from the production of ethanol. Depending on the way it is processed, the processing yields several beneficial products, some of which are used for food production and feedstocks.

[ Ethanol fuel cells

Main article: Direct-ethanol fuel cell

Ethanol may be used as a fuel to power Direct-ethanol fuel cells (DEFC) in order to produce electricity and the by-products of water (H₂O) and carbon dioxide (CO₂).^[70] Platinum is commonly used as an anode in such fuel cells in order to achieve a power density that is comparable to competing technologies. Until recently the high price of platinum has been cost prohibitive. A company called Acta Nanotech has created platinum free nanostructured anodes using more common and therefore less expensive metals.^[71] A vehicle using a DEFC and non-platinum nanostructured anodes was used in the Shell Eco-Marathon 2007 by a team from Offenburg Germany which achieved an efficiency of 2716 kilometers per liter (6388 miles per gallon).^[72]

[ Rocket fuel

Ethanol was commonly used as fuel in early bipropellant rocket vehicles, in conjunction with an oxidizer such as liquid oxygen. The German V-2 rocket of World War II, credited with beginning the space age, used ethanol, mixed with water to reduce the combustion chamber temperature.^[73][74] The V-2"s design team helped develop U.S. rockets following World War II, including the ethanol-fueled Redstone rocket, which launched the first U.S. satellite.^[75] Alcohols fell into general disuse as more efficient rocket fuels were developed.^[74]

[Alcoholic beverages

Main article: Alcoholic beverage

Ethanol is the principal psychoactive constituent in alcoholic beverages, with depressant effects on the central nervous system. It has a complex mode of action and affects multiple systems in the brain, most notably ethanol acts as an agonist to the GABA receptors.^[76] Similar psychoactives include those which also interact with GABA receptors, such as gamma-hydroxybutyric acid (GHB).^[77] Ethanol is metabolized by the body as an energy-providing carbohydrate nutrient, as it metabolizes into acetyl CoA, an intermediate common with glucose metabolism, that can be used for energy in the citric acid cycle or for biosynthesis.

Alcoholic beverages vary considerably in their ethanol content and in the foodstuffs from which they are produced. Most alcoholic beverages can be broadly classified as fermented beverages, beverages made by the action of yeast on sugary foodstuffs, or as distilled beverages, beverages whose preparation involves concentrating the ethanol in fermented beverages by distillation. The ethanol content of a beverage is usually measured in terms of the volume fraction of ethanol in the beverage, expressed either as a percentage or in alcoholic proof units.

Fermented beverages can be broadly classified by the foodstuff from which they are fermented. Beers are made from cereal grains or other starchy materials, wines and ciders from fruit juices, and meads from honey. Cultures around the world have made fermented beverages from numerous other foodstuffs, and local and national names for various fermented beverages abound.

Distilled beverages are made by distilling fermented beverages. Broad categories of distilled beverages include whiskeys, distilled from fermented cereal grains; brandies, distilled from fermented fruit juices, and rum, distilled from fermented molasses or sugarcane juice. Vodka and similar neutral grain spirits can be distilled from any fermented material (grain or potatoes are most common); these spirits are so thoroughly distilled that no tastes from the particular starting material remain. Numerous other spirits and liqueurs are prepared by infusing flavors from fruits, herbs, and spices into distilled spirits. A traditional example is gin, which is created by infusing juniper berries into a neutral grain alcohol.

In a few beverages, ethanol is concentrated by means other than distillation. Applejack is traditionally made by freeze distillation, by which water is frozen out of fermented apple cider, leaving a more ethanol-rich liquid behind. Eisbier (more commonly, eisbock) is also freeze-distilled, with beer as the base beverage. Fortified wines are prepared by adding brandy or some other distilled spirit to partially-fermented wine. This kills the yeast and conserves some of the sugar in grape juice; such beverages are not only more ethanol-rich, but are often sweeter than other wines.

Alcoholic beverages are sometimes used in cooking, not only for their inherent flavors, but also because the alcohol dissolves hydrophobic flavor compounds which water cannot.

همه مولکولها را می‌توان بر حسب تقارنهای آنها تعریف کرد، حتی اگر فقط بگوییم که آنها ، هیچ تقارنی ندارند. مولکولها یا اجسام دیگر ممکن است دارای عناصر تقارن نظیر صفحه‌های آینه‌ای ، محورهای چرخشی و مراکز وارونگی باشند. انعکاس ، چرخش یا وارونگی واقعی را عمل تقارن می‌نامند. اکثر این عناصر و اعمال تا اندازه ای آشنا هستند، اما برای کاربردهای عملی در شیمی باید کاملا با آن آشنا شد.

برای اینکه مولکولی ، عنصر تقارن معینی را داشته باشد، شکل ظاهری آن بعد از عمل تقارن که از زاویه یکسانی از مولکول گرفته شده است (اگر چنین عکسهایی امکان پذیر باشند) باید غیرقابل تشخیص باشند. اگر بعد از انجام یک عمل تقارنی ، مولکول حاصل به هر طریقی از مولکول اولیه قابل تشخیص باشد، در آن صورت ، آن عمل ، جزو اعمال متقارن مولکول نیست.

عمل یکسانی (E)

اولین عمل ، عمل یکسانی (E) است که به‌منظور تکمیل مجموعه اعمال ریاضی گنجانده شده است. این عمل ، هیچ تغییری در مولکول ایجاد نمی‌کند. هر مولکولی ، یک عمل یکسانی دارد، حتی اگر هیچ تقارنی نداشته باشد.

عمل انعکاسی (?)

عمل بعدی ، عمل انعکاسی (?) ، موقعی وجود دارد که مولکول ، دارای یک صفحه آینه‌ای باشد. اگر جزئیاتی نظیر آرایش موها و محل اندامهای داخلی را در نظر نگیریم، بدن انسان دارای یک صفحه آینه‌‌ای چپ – راست می‌باشد. بسیاری از مولکولها ، صفحه آینه‌ای دارند، اگرچه ممکن است در نگاه اول آشکار نباشد. عمل انعکاس ، جای چپ و راست را عوض می‌کند، مانند اینکه هر نقطه به‌طور عمود از میان صفحه به موقعیتی دقیقا در همان فاصله از صفحه که در آغاز بود، حرکت کرده است.

مولکولها می‌توانند به هر تعدادی صفحه آینه‌ای داشته باشند. اجسام خطی نظیر یک مداد چوبی گرد یا مولکولهای همچون استیلن و کربن دی‌اکسید دارای تعداد نامحدودی صفحه آینه‌ای هستند که همه آنها دربرگیرنده محور مرکزی جسم می‌باشند.

عمل چرخشی (C_n)

عمل چرخشی که چرخش متعارف نیز نامیده می‌شود، مستلزم چرخش به اندازه 360بر n درجه حول محور چرخش است. CHCl₃ نمونه ای از مولکولهایی است که دارای محور درجه سه (C₃) می‌باشند و در آن ، محور چرخش بر محور پیوند C-H منطبق است. اگر چرخش C₃ دوبار پشت سرهم انجام می‌گیرد، یک چرخش جدید ?240حاصل می‌شود که با C²₃ نشان داده شده و جزو اعمال تنقارن مولکولی نیز می‌باشد.

سه عمل متوالی C₃ برابر عمل یکسانی است (C³₃=E) که در همه مولکولها وجود دارد. بسیاری از مولکولها و اجسام دیگر محورهای چرخش متعددی دارند.

دانه‌های برف

دانه‌های برف ، نمونه‌هایی در این مورد هستند، با شکلهای پیچیده ای که معمولا شش گوشه‌ای تقریبا مسطح است. خطی که عمود بر صفحه دانه برف از مرکز آن گذشته ، دربرگیرنده یک محور درجه دو (C₂) ، یک محور درجه سه (C₃) و یک محور درجه شش (C₆) است. دقت کنید که چرخش به اندازه ?240 (C²₃) و ?300 (C⁵₆) نیز جزو اعمال تقارن دانه برف می‌باشند.

همچنین دو مجموعه سه‌تایی دیگر از محورهای C₂ در صفحه دانه برف وجود دارد که یک مجموعه از نقطه‌های متقابل و مجموعه دیگر از وسط اضلاع میان نقطه‌ها می‌گذرد. در مولکولهای دارای بیش از یک محور چرخشی ، محور C_n دارای بزرگترین مقدار n ممکن به‌عنوان محور چرخش با بزرگترین مرتبه یا محور اصلی تعیین می‌شود.

محور چرخش با بزرگترین مرتبه در دانه برف ، محور C₆ است. (در موقع انتقال به مشخصات کارتزین ، محور C_n با بزرگترین مرتبه معمولا به‌عنوان محور Z انتخاب می‌شود). در صورت لزوم ، محورها C₂ عمود بر محور اصلی را با پریم مشخص می‌کنند. یک تک پریم نشان می‌دهد که محور از داخل چندین اتم مولکول می‌گذرد، در حالی‌که یک جفت پریم نشان می‌دهد که محور از بین اتمها می‌گذرد.

عمل وارونگی (i)

این عمل ، کمی پیچیده‌تر است. هر نقطه از وسط مرکز مولکول به موقعیتی مقابل موقعیت اولیه حرکت می‌کند، به‌طوری‌که فاصله اش از نقطه مرکزی برابر با فاصله ای باشد که در آغاز داشت. اتان در حالت صورتبندی نامتقابل نمونه ای از مولکولهایی است که دارای مرکز وارونگی می‌باشند. بسیاری از مولکولها که در نگاه اول به نظر می‌رسد مرکز وارونگی دارند، فاقد آن هستند. متان و مولکولهای چهار وجهی دیگر ، نمونه‌هایی از این مولکولها هستند.

اگر دو اتم هیدروژن یک مدل متان در صفحه عمودی سمت راست و دو اتم هیدروژن دیگرش در صفحه افقی در چپ نگاه داشته شود، عمل وارونگی دو هیدروژن واقع در صفحه افقی را به سمت راست و دو هیدروژن واقع در صفحه عمودی را به سمت چپ منتقل می‌کند. پس متان ، عمل وارونگی ندارد، چون جهت‌گیری مولکول پس از عمل i با جهت‌گیری اولیه متفاوت است.

بطور کلی ، چهار وجهی‌ها ، مسطح مثلثی‌ها ، پنج ضلعی‌ها مرکز وارونگی ندارند. مربعها ، متوازی‌الاضلاعها ، اجسام راست‌گوشه و دانه‌های برف مرکز وارونگی دارند.

عمل چرخش- انعکاس (S_n)

این عمل که گاهی اوقات ، چرخش نامتقارن نامیده می‌شود، مستلزم چرخش به اندازه 360 بر n درجه و به دنبال آن ، انعکاس از صفحه عمود بر محور چرخش می‌باشد. برای مثال ، در متان ، خطی که از وسط کربن عبور کرده و زاویه میان هیدروژنها را در طرفین نصف می‌کند، یک محور S₄ می‌باشد. از این نوع خط سه تا و در کل سه محور S₄ وجود دارد. این عمل ، مستلزم چرخش مولکول به اندازه ?90 و سپس انعکاس از صفحه آینه‌ای عمود می‌باشد. دو عمل متوالی S_n یک محور C_n/2 ایجاد می‌کند. در متان ، دو عمل S₄ یک C₂ ایجاد می‌کند.

بعضی وقتها ممکن است محور S_n مولکول با محور C_n آن منطبق باشد. مثلا دانه‌های برف ، علاوه بر محورهای چرخش اشاره شده در بالا ، محورهای S₂ ، S₃ و S₆ منطبق بر محور C₆ نیز دارند. دقت کنید که محور S₂ با وارونگی و محور S₁ با صفحه آینه‌ای یکسانی هستند. در مورد اول ، نماد i و در مورد دوم نماد ? ترجیح داده می‌شود.