Biochemical Engineers and Evaluators will be combined to form an efficient occupation making the world a more efficient. Biochemical Engineers develop tangible products using knowledge of biology, chemistry, and engineering to balance our everyday predicaments. Predicaments such as materials, systems, or processes that interact with humans, plants, animals, microorganisms, and biological materials being in contact. An Evaluators niche is to judge the quality, quantity and value of an object’s worth. The career will most definitely be difficult than the two combined jobs alone.
Combining the two together creating a new occupation, a Biochemical Engineer Evaluator we can change our world making the organisms that live among feel that they are worth something. While Biochemical Engineer Evaluators have the knowledge to develop usable products to increase the evolution of the Earth. Biochemical Engineer Evaluators can have unsuspecting setbacks. Biochemical Engineer Evaluators can determine what tangible products have expired over the course of a year with research of evidence. Our planet can not survive on its own without a little help from the users which are tearing the very core apart.
We have so much that we could do to accelerate the health of the Earth. Organizations have been put into effect yet these organizations are not enough to make the Earth a better living space for every single organism. With Biochemical Engineer Evaluators, Earth activists, The planetary society, and many more organizations we can stop this rollercoaster of a statistical decline of our Earth’s precious atmosphere. Our ProblemsOur most problematic situation Biochemical Engineer Evaluators will solve in the near future will be air pollution.
Air pollution damages the environment as well as our health. The ozone can damage crops and other vegetation, impairing growth. These impacts, can reduce the ability of plants to take up CO2 from the atmosphere and indirectly affect entire ecosystems and the planet’s climate. The atmospheric deposition of sulfur and nitrogen compounds has acidifying effects on soils and freshwaters. Acidification causes disturbances in the function and structure of ecosystems with harmful ecological effects, including biodiversity loss. Likewise, deposition of nitrogen compounds can lead to eutrophication, which constitutes an oversupply of nutrient nitrogen in terrestrial and aquatic ecosystems. Consequences include changes in species diversity, invasions of new species and leaching of nitrate to groundwater.
Our selfish ways of polluting the air will one day change because of our cautious Biochemical Engineer Evaluators. Air pollution causes the Earth to not be its “tip-top” shape and the evaluation part of the Biochemical Engineer Evaluator will be to choose the most effective non-polluting substance to replace the pollution population (Informaci, ‘Chemicals harmful to the atmosphere’, 2012, p. 1).One of the many situations we have today would be radioactive decay. Radioactive decay is the breakdown of an atomic nucleus releasing energy and matter from the nucleus. Ordinary double-beta decay is an unusual mode of radioactivity in which a nucleus emits two electrons and two antineutrinos at the same time. However, if neutrinos and antineutrinos are identical; then, the two antineutrinos can, in effect, cancel each other, resulting in a neutrinoless decay, with all the energy given to the two electrons. The nucleus is the most important part of a cell. What would a person do if objects started going into thin air? The releasing of energy could cause an opposite reaction that humans haven’t quite researched enough. Biochemical Engineers right now are trying to figure out the possibilities of what would become of that atom. The Evaluator portion of Biochemical Engineer Evaluators will help prune the unsure breaking down of an atomic atom. The field of Biochemical Engineer Evaluators can fix the slightest rotation of what we had in mind for the unsuspecting atomic breakdown (ScienceDaily, ‘New device uses biochemistry techniques to detect rare radioactive decays’, 2018, p. 1).Heated topics that we could fixGlobal warming is a largely discussed topic. What could we help to not make global warming become an epidemic? We could put the best chemical balance experts out to evaluate what we could do to fix our situation with a permanent solution. The three-layer atmosphere model represented to refer to as we apply the analysis of this model to what is observed in the Earth’s atmosphere. The IR-absorbing gases amongst the atmosphere is an element we also have to account for also the absorptions of different strengths and for condensable and non-condensable gases. Absorption strengths are at one extreme wavelength where none of the atmospheric gases absorb IR radiation. IR radiation is where all the emissivities in the diagram above are zero.In this case, the radiation leaving the atmosphere all comes from the surface and is characterized by its temperature, TP. Wavelengths where atmospheric gases absorb, but relatively weakly emissivities in the higher, colder layers are zero. The radiation leaving the atmosphere comes from a layer of intermediate temperature.
In the diagram, this might correspond to a wavelength for which ε3 is zero, so the radiation observed outside the atmosphere would be coming from the layer with the temperature T2. This information can change our efforts into a different category to per find the source of the problem to produce a solution (American Chemical Society, ‘Application to Earth’s Atmosphere’, 2018, p. 1). Future of Biochemical EngineeringThe book on Biochemical Engineering; A Textbook For Engineers, Chemists, and Biologists, 2nd, completely revised, and enlarged edition. The central theme of the textbook remains the application of chemical engineering principles to biological processes in general, demonstrating how a chemical engineer would address and solve problems. To create a logical and clear structure, the book is divided into three parts. The first deals with the basic concepts and principles of chemical engineering and can be read by those students with no prior knowledge of chemical engineering. The second part focuses on process aspects, such as heat and mass transfer, bioreactors, and separation methods. Finally, the third section describes practical aspects, including medical device production, downstream operations, and fermenter engineering (Katoh, Horiuchi, & Yoshida, Biochemical engineering: a textbook for engineers, chemists and biologists, 2015, p. summary).Gravity’s effectAn improved understanding of the biochemical effects of microgravity could also help patients with limited mobility on Earth, such as those on bed rest. Understanding how various physiological systems respond and interact with changing gravity conditions could help physicians design different treatments or exercises for people with limited mobility. NASA really helps humans understand that Biochemical Engineers do not only help fix problems, they also assist in the understanding of the unknown, or the barely understood obstacles. Cells are exposed to a variety of physical forces, generated by the association with other cells and extracellular matrices, by polymerization/depolymerization reactions of cytoskeletal elements, and by the constant forces placed on cells by gravity. Such forces can result in alterations in the cellular biochemistry. Illustrative in this respect is a gravity perception in specialized plant root cells, the osteocytes, which are localized in the mot tip. In osteocytes, small cell organelles (amyloplasts) sediment according to the gravity vector toward the basal cell wall. Through an unknown mechanism, this triggers biochemical stimuli that lead to the induction of unidirectional cell proliferation along the gravity vector. This response is absent in microgravity.
Changes in the gravitational environment may also lead to biochemical alterations in animal cells. Exposure of rats to microgravity, or immobilization of rats, leads to a change in calcium homeostasis, which results in the inhibition of bone formation. Increased gravity values also affect cellular processes. In, human epithelial carcinoma cell line (HeLa cells), hypergravity leads to alterations in the expression of specific nuclear genes. Hypergravity enhances the expression of the c-myc proto oncogene, which is associated with a reduction of the duration of the G1 cell cycle phase and results in stimulation of proliferation of these cells. Although studies such as these have demonstrated the translation of sometimes subtle mechanical stimuli into biochemical signals, no clues have been provided as to the molecular mechanisms involved. This study using biochemical engineering is absolutely perfect for the biochemical effect gravity has on our fragile bodies.Earth The Earth has a lot of species that Biochemical Engineer Evaluators need to relocate to save Earth. When an invasive species starts wreaking havoc on an ecosystem because it has no natural predators to keep its population in check, it may seem like a good idea to introduce a predator to control it. Unfortunately, this doesn’t always work out so well. A famous example in ecological textbooks is the introduction of the animal, Cane Toad, in Australia. Cane Toads were introduced to continue the extinction of the Cane Beetle, that was devastating the sugar cane crop in Australia. This failed miserably as the toads were unable to eat many of the beatles. However, they did thrive by feeding on other insect species and harmed potential predators of the toad with toxins they could emit from their skin. Generally, vertebrates are a bad choice for biological control agents because they usually do not specialize on a specific target species. Therefore, they will impact other aspects of the ecosystem. Since this mistake almost 100 years ago, scientists have recognized the risks of introducing biological control agents and now conduct rigorous testing before releasing any biocontrol agents into the wild (Alcott, ‘4 ways humans harm the environment (when they are trying to help)’, 2016, p. 2).SoulutionsAccording to the Environmental Protection Agency (EPA), the average adult breathes 3,000 gallons of air per day, yet the same air that fuels our bodies and can also harm them. In fact, inhaling certain air pollutants can worsen conditions such as asthma, and studies estimate that thousands of people die prematurely each year due to air pollution. Tracey Holloway, a University of Wisconsin-Madison professor with appointments in the Nelson Institute for Environmental Studies, Civil and Environmental Engineering, and Atmospheric and Oceanic Sciences, is tackling the real problem of air pollution through her research and teaching at UW-Madison. ‘I want to understand what is in the air we breathe and how is air pollution affected by energy uses, such as electricity use and transportation,’ Holloway says. ‘I study air quality to inform both public health and public policy.’
In particular, Holloway focuses on health-damaging chemicals in the air, using computer models that have roots in engineering.The models use fluid dynamics equations to represent pollutants in the air. ‘The models help us estimate how energy choices affect the air. Like, if fewer nitrogen oxides were being emitted from cars, what would that mean for the number of smoggy days in a particular city,’ Holloway says. These studies are effective to help the air pollution dilemma (Science x Network, ‘Engineers are making strides in reducing air pollution’, 2003-2018, p. 1).Radiation is part of our life. Fortunately, there are slim situations where an average person is exposed to uncontrolled sources of radiation above the ground. Three ways to be safe from radiation; Time: people who are exposed to radiation gives off radiation Energy as either particles or rays. In addition to natural background radiation, limiting or minimizing the exposure time reduces the dose from the radiation source. Distance: Just as the heat from a fire reduces as you move further away, the dose of radiation decreases dramatically as you increase your distance from the source. Shielding: Barriers of lead, concrete, or water provide protection from penetrating gamma rays. A form of ionizing radiation that is made up of weightless packets of energy called photons. Gamma rays can pass completely through the human body; as they pass through, they can cause damage to tissue, DNA, and x-rays. A form of ionizing radiation made up of photons. X-rays are capable of passing completely through the human body. Medical x-rays are the single largest source of man-made radiation exposure. This is why certain radioactive materials are stored under water or in concrete or lead-lined rooms, and why dentists place a lead blanket on patients receiving x-rays of their teeth. Therefore, inserting the proper shield between you and a radiation source will greatly reduce or eliminate the dose you receive.Gas-smart cars, such as hybrids and fully electric vehicles, save fuel and money. Once all cars and light trucks meet 2025’s clean car standards, which means averaging 54.5 miles per gallon, they’ll be a mainstay. For good reason: Relative to a national fleet of vehicles that averaged only 28.3 miles per gallon in 2011, Americans will spend $80 billion less at the pump each year and cut their automotive emissions by half. Before you buy a new set of wheels, compare fuel-economy performance. This can help with our global warming epidemic. Conclusion With all of these situations we put ourselves in and insignificant solutions, we need to create solutions together. The different organizations need to be together to fight the instability of our Earth’s balance. Biochemical Engineer Evaluators can fix many of the situations we have caused just living carelessly.