Chemistry TAS Report Essay Example for Free

Chemistry TAS Report Essay 1. Experiment Number : 10 2. Date : 18/01/2008 3. Title : Determination of the equilibrium constant for the reaction : Fe3+(aq) + SCN-(aq) = FeSCN2+(aq) 4. Aims/Objective : To determine the equilibrium constant for the reaction : Fe3+(aq) + SCN-(aq) = FeSCN2+(aq) 5. Introduction / Theory: In this experiment, the equilibrium constant for the formation of a complex ion, FeSCN2+(aq), is determined. Complex ions, thiocyanatoiron(III) ions, are formed from iron(III) ions and thiocyanate ions in aqueous solution : Fe3+(aq) + SCN-(aq) = FeSCN2+(aq) (1). see more:chemistry matriculation notes semester 1 The equilibrium constant for this reaction is:Kc = [FeSCN2+(aq)] (2) [Fe3+(aq)][SCN-(aq)] The product complex ion is the only one of the three species which has an appreciable color (blood-red). 6. Relevant Equations/Chemical Reactions Involved : Fe3+(aq) + SCN-(aq) = FeSCN2+(aq) 7. Chemicals : 0. 002 M KSCN(aq) 50 cm3 0. 2 M Fe(NO3)3(aq) 20 cm3 8. Apparatus and equipment : Boiling tube 5 Dropper 2 10 cm3 measuring cylinder 1 Lamp 1 25 cm3 measuring cylinder 1 Wash bottle 1 Safety spectacle 1 250 cm3 beaker 1 9. Procedure : 1. 0. 2 M Fe(NO3)3(aq) was used and 10 cm3 of 0. 08 M, 0. 032 M, 0. 0128 M, 0. 00512 M Fe(NO3)3(aq) were prepared respectively. The solutions were added by using 10 cm3 measuring cylinder to 5 clean boiling tubes in a rack as below. Tube No. 1 2 3 4 5 SCN-(aq) / cm3 10 10 10 10 10 Fe3+(aq) / cm3 10(0. 2 M) 10(0. 08 M) 10(0. 032 M) 10(0. 0128 M) 10(0. 00512 M) 3. Tubes 1 and 2 were wrapped around with a strip of paper so that light was excluded from the side. 4. The solutions towards the lamp were looked vertically down to compare the colour intensity. 5. Some of the solution from the standard tube 1 was removed with a dropper until the colour intensities of solutions in both tubes were the same. And the removed liquid was put into a clean and dry beaker. 6. The depth of the solution in tube 1 was then measured. 7. Steps 3 to 6 were repeated with tubes 1 and 3, 1and 4 and finally 1and 5. 10. Observations : The colour intensities of the solutions in the two tubes being observed were the same. 11. Data, Calculation and Results : Height of solution in original tube 1 = 59 mm Height of solution in tube 1 having the same colour intensity as tubes 2, 3, 4 and 5 are : Same colour intensity as 2 3 4 5 Height of solution in tube 1 (mm) 45 35 28 23 12. Conclusion : The equilibrium constant for the reaction : Fe3+(aq) + SCN-(aq) = FeSCN2+(aq) was found to be 82. 1 M-1. 13. Discussion : 1. By M1V1 = M2V2, For tube 1, initial concentration of SCN-(aq) = 0. 001 M initial concentration of Fe3+(aq) = 0. 1 M For tube 2, initial concentration of SCN-(aq) = 0. 001 M initial concentration of Fe3+(aq) = 0. 04 M For tube 3, initial concentration of SCN-(aq) = 0. 001 M initial concentration of Fe3+(aq) = 0. 016 M For tube 4, initial concentration of SCN-(aq) = 0. 001 M initial concentration of Fe3+(aq) = 0. 0064 M For tube 5, initial concentration of SCN-(aq) = 0. 001 M initial concentration of Fe3+(aq) = 0. 00256 M 2. Concentration of FeSCN2+ in tube 1 = 0.001 M 3. Ratio of depth in the colour comparison with tube 2 = 45 /59 = 0. 763 Ratio of depth in the colour comparison with tube 3 = 35 /59 = 0. 593 Ratio of depth in the colour comparison with tube 4 = 28 /59 = 0. 475 Ratio of depth in the colour comparison with tube 5 = 23 /59 = 0. 390 Equilibrium concentration of thiocyanoiron(III) ions: In tube 2 = 0. 001 x (45 / 59) = 7. 63 x 10-4 M In tube 3 = 0. 001 x (35 / 59) = 5. 93 x 10-4 M In tube 4 = 0. 001 x (28 / 59) = 4. 75 x 10-4 M In tube 5 = 0. 001 x (23 / 59) = 3. 90 x 10-4 M 4. [Fe3+]equil = [Fe3+]initial [FeSCN2+]equil = 0. 04 7. 63 x 10-4 = 0. 0392 M [SCN-]equil = [SCN-]initial [FeSCN2+]equil = 0. 001 -7. 63 x 10-4 = 2. 37 x 10-4 M 5. Room temperature = 16 oC K = [FeSCN2+]equil / ([Fe3+]equil[SCN-]equil) = 7. 63 x 10-4 / [(0. 0392)(2. 37 x 10-4)] = 82. 1 M-1 6. There are few sources of error in this experiment. (1) Determination of colour intensity in the two tubes observed might not be accurate. (2) Taking reading when measuring the depth of liquid. Error estimation When taking initial reading, error is + 0. 05 cm3. When taking final reading, error is also + 0. 05 cm3. Therefore, error is + 0. 1 cm3.

Morality and Gay Rights Discourse Essay -- Gay Rights Ethics Essays

Morality and Gay Rights Discourse When Aristotle discussed the material premises of enthymemes as being important in rhetoric, he was prescient of the kind of appeals that would be tendered by opponents in the discourse over gay rights issues long after his time. Smith and Windes express the nature of this conflict accurately when they write, â€Å"symbols expressing fundamental cultural values are invoked by all sides† (1997: 28). Similarly, Sarah S. Brown describes the participants in a â€Å"struggle to stake out symbolic positions of good and to frame their side in terms of morally powerful conceptions of right and wrong† (2000: 458). Fascinatingly, she suggests, â€Å"even people with deeply conflicting opinions appeal to the same moral concepts for the force of their arguments† (458). In fact, these same moral concepts are ubiquitous to all discourse and to life. They penetrate the social order at the most fundamental level. They are not static, however, and their malleability gives rise to a constantly shifting landscape of debate wherein, as Smith and Windes (1997) assert, the adversaries literally have so much impact as to drive the process of self-definition for one another. Related to that process is the way in which the landscape itself is defined, which Haider-Markel and Meier see as consequential in terms of â€Å"what resources are important and [what] advantages some coalitions [in the struggle] have over others† (1996: 346). (See also: Kintz, 1998; Smith and Windes, 1997). Particularly, they demonstrate that models of discourse which conceptualize gay issues in terms of morality (or culture) as opposed to politics or civil rights offer a rhetorical upper hand to proponents of anti-gay arguments. It is the objectiv... ...vation in Gay Rights/Special Rights.† In: Kintz, Linda and Lesage, Julia. 1998. Media , Culture, and the Religious Right. Minneapolis: University of Minnesota Press. Patten, Steve. â€Å"Preston Manning’s Populism: constructing the common sense of the common people.† Studies in Political Economy, Vol.50 (Summer, 1996): 95 Schulze, Laurie and Guilfoyle, Frances. â€Å"Facts Don’t Hate; They Just Are.† In: Kintz, Linda and Lesage, Julia. 1998. Media , Culture, and the Religious Right. Minneapolis: University of Minnesota Press. Smith, Ralph R. and Windes, Russel R. â€Å"The Progay and Antigay Issue Culture: Interpretation, Influence, and Dissent.† Quarterly Journal of Speech, Vol. 83 (1997): 28-48 Terry, Jennifer. â€Å"Unatural Acts In Nature: The Scientific Fascination with Queer Animals.† QLQ: A Journal of Lesbian and Gay Studies, Vol.6.2 (2000): 151-193

Biological Effects Of Radiation Environmental Sciences Essay

Radiation describes a procedure in which energetic atoms or moving ridges travel through a medium or infinite. There are two distinguishable types of radiation ; ionising and non-ionizing. The word radiation is normally used in mention to ionising radiation merely holding sufficient energy to ionise an atom but it may besides mention to non-ionizing radiation illustration like wireless moving ridges or seeable visible radiation. The energy radiates travels outward in consecutive lines in all waies from its beginning. This geometry of course leads to a system of measuring and physical that is every bit applicable to all types of radiation. Both ionising and non-ionizing radiation can be harmful to beings and can ensue in alterations to the natural environment. Radiation with sufficiently high energy can ionise atoms. Most frequently, this occurs when an negatron is stripped from an negatron shell, which leaves the atom with a net positive charge. Because cells are made of atoms, this ionisation can ensue in malignant neoplastic disease. An single cell is made of millions of atoms. The chance of ionising radiation doing malignant neoplastic disease is dependent upon the dose rate of the radiation and the sensitiveness of the being being irradiated. Alpha atoms, Beta atoms, Gamma and X-Ray radiation, and Neutrons may all be accelerated to a high plenty energy to ionise atoms. Alpha atom: In alpha atom, the self-generated procedure of emanation of an alpha atom from a radioactive karyon. Alpha atom is by and large termed as alpha decay. An alpha atom is emitted by a heavy karyon. The karyon, called parent karyon has a really big internal energy and is unstable. An alpha atom is a He nucleus holding two protons and two neutrons. When two negatrons revolving around the karyon of He atom are knocked out wholly, we have double ionized He atom known as alpha atom. Beta atom: a beta-particle is a fast moving negatron. The self-generated procedure of emanation of beta-particle from a radioactive karyon is called beta decay. Beta decay is of three types: beta-minus, beta-plus, and electron gaining control. Beta-minus: beta-minus is like an negatron. It is surprising that nucleus contains no negatron, so a karyon can breathe negatron. In the neutron inside the karyon is converted in to a proton and an negatron like atom. This negatron like atom is emitted by the karyon during beta-decay. In beta-minus decay, neutron in the karyon is converted in to a proton and a beta-minus atom is emitted so that the ratio of neutron to proton lessenings and therefore the nucleus becomes stable. Beta-plus: In a beta-plus decay, a proton is converted in to a neutron and a antielectron is emitted if a karyon has more protons than neutrons. Electron gaining control: In negatron gaining control, nucleus absorbs one of the interior negatrons go arounding around it and hence a atomic proton becomes a neutron and a neutrino is emitted. Electron gaining control is comparable with a antielectron emanation as the procedures lead to the same atomic transmutation. However, in negatron gaining control occurs more often than antielectron emanation in heavy elements. This is because the orbits of negatrons in heavy elements have same radii and hence orbital negatrons are really near to the karyon. Gamma beam: Gamma beams are the high energy packages of electromagnetic radiation. Gamma radiations have high energy photons. They do non hold any charge and their comparative remainder mass is zero. Gamma-decay it is the self-generated procedure of emanation of high energy photon from a radioactive karyon. When a radioactive karyon emits a beta atom, the girl karyon is excited to the higher energy province. This aroused karyon beams are emitted by the girl nucleus so it is clear that the emanation of gamma beams follows the emanation of alpha or beta atom.Non ionising radiation:Non-ionizing signifiers of radiation on life tissue have merely late been studied. Alternatively of bring forthing charged ions when go throughing through affair, the electromagnetic radiation has sufficient energy to alter merely the rotational, quiver or electronic valency constellations of molecules and atoms. However, different biological effects are observed for different types of non-ionizing radiation Radio moving ridges: Radio moving ridges whose wavelengths range from than 10^4m to 0.1m, are the consequence of charges speed uping through carry oning wires. They are generated by such electronic devices as LC oscillators are used in wireless and telecasting communicating system. Infrared beams: Infrared radiations have wavelength runing from about 0.3m to 10^ -4m and besides generated by the electronic devices. The infrared radiation energy absorbed by a substance as internal energy because the energy agitates the object ‘s atoms, increasing their quiver or translational gesture, which consequences temperature increases. Infrared radiation has practical and scientific application in many countries, including physical therapy, infrared radiation picture taking, and quiver spectrometry. Ultraviolet radiation: Ultraviolet radiation screen wavelength runing from about 4X10^4m to 6X10^-10m. The Sun is an of import beginning of ultraviolet radiation visible radiation, which is the chief cause of tan. Sunscreen locations are crystalline to seeable visible radiation but greater per centum of UV visible radiation absorbed. Ultraviolet beams have besides been implicated I the formation of cataracts. Most of the UV visible radiation from the Sun is absorbed by ozone molecules in the Earth upper ambiance, in a bed called stratosphere. This ozone shield converts lethal high energy UV radiation to infrared radiation, which in bends warm the stratosphere. X raies: X raies have the scope from approximately10^-8 to 10^-12m. The most common beginning of X raies is halting of high energy negatrons upon the pelting a metal mark. X raies are used as nosologies tool in medical specialty and as the intervention for certain signifiers of malignant neoplastic disease. Because X raies can damage or destruct living tissue and being, attention must be taken avoid necessary exposure or over-exposure. X raies are besides used in the survey of crystal construction because x-rays wavelengths are comparable to the atomic separation distance in solids. Electromagnetic radiation: The wave nature of electromagnetic radiation explains assorted phenomena like intervention, diffraction and polarisation. However, wave nature of electromagnetic radiation, could explicate phenomena like photoelectric consequence, Compton Effect. The cathode rays consist of negative charged atoms called negatrons which are the component of an atom and therefore the component of affair. Harmonizing to the construct of radiation illustration light moving ridge ‘s wireless moving ridges, X raies, microwaves etc. are assumed to transport energy in packages or packages known as photons or quanta.Biological consequence of radiation:In biological consequence of radiation, there are many unsafe effects of our wellness and organic structure. Biological effects of radiation are typically can be divided into two classs. The first category consist of exposure to high doses of radiation over shots period of clip bring forthing ague or short term effects. The 2nd class represents exposure to low doses of radiation over an drawn-out period of clip bring forthing chronic or long term effects. High dosage ( acute ) : high doses tend to kill cells, while low doses tend to damage or alter them. High doses can kill so many cells that tissues and variety meats are damaged. This is bend may do a rapid whole organic structure response frequently called the ague radiation syndrome ( ARS ) . Low doses ( chronic ) : low doses spread out over long periods of clip do n't do an immediate job to any organic structure organ. The effects of low doses of radiation occur at the degree of the cell, and the consequences may non be observed for many old ages. Although we tend to tie in high doses of radiation with ruinous events such as atomic arms detonations, there have been documented instances of persons deceasing from exposures to high doses of radiation ensuing from tragic events. High effects of radiation: high effects of radiation are skin Burnss, hair loss, asepsis, cataracts. Effectss of skin include ( blushing like tan ) , dry ( skining ) , and moist ( vesicating ) . Skin effects are more likely to happen with exposure to moo energy gamma, x-ray, or beta radiation. Most of the energy of the radiation sedimentation in the skin surface. The dosage required for erythematic to happen is comparatively high, in surplus of 300 radiations. Blistering requires a dosage in surplus of 1,200 radiations. Hair loss, besides called epilation, is similar to clamber effects and can happen after acute doses of about 500 radiations. Asepsis can be impermanent or lasting in males, depending upon the doses. To bring forth lasting asepsis, a dosage in surplus of 400 radiations is required to the generative variety meats. Cataracts ( a clouding of the lens of the oculus ) appear to hold a threshold about 200 radiations. Neutrons are particularly effectual in bring forthing cataracts, because the oculus has high H2O content, which is peculiarly effectual in halting neutrons.High dose effects:Dose ( radiation ) consequence observed15-25 blood count alterations. 50 blood count alteration in single. 100 Vomiting ( threshold ) . 150 Death ( threshold ) .Classs of effects of exposure to low doses of radiation:There are three general classs of effects ensuing from exposure to low doses of radiation. These are: Familial: the consequence is suffered by the progeny of the person exposed. Bodily: the consequence is chiefly suffered by the person exposed. Since malignant neoplastic disease is the primary consequence, it is sometimes called the carcinogenic consequence. In-utero: some erroneously consider this to be a familial effect of radiation exposure, because the consequence, suffered by a development is after birth. However, this is really a particular instance of the bodily consequence, since the embryo is the 1 to the radiation. Radiation hazard: the approximative hazards for the three chief effects to degree of radiation are: In familial consequence, hazard from 1 paradoxical sleep of radiation exposure to the generative variety meats about 50 to 1,000 clip ‘s less than self-generated hazard for assorted anomalousnesss. In bodily consequence, for radiation induced malignant neoplastic disease, the hazard estimation is developing any type of malignant neoplastic disease. However non all malignant neoplastic diseases are associated with exposure to radiation. The hazard from deceasing from radiation induced malignant neoplastic disease is about one half the hazard of acquiring the malignant neoplastic disease. In utero: Spontaneous hazards of foetal abnormalcies are about 5 to 30 times greater than hazard of exposure to 1 paradoxical sleep radiation. However, the hazard of child goon malignant neoplastic disease from exposure in utero is about the same as the hazard to grownups exposed to radiation exposures. Linear no-threshold hazard theoretical account: general consensus among experts is that some radiation dosage by a additive, no threshold theoretical account. This theoretical account is accepted by the NRC since it appears to be most conservative. Linear: an addition in dose grownups in a relative addition in hazard. No-threshold: any dosage, no affair how little, produces some hazard. The hazard does non get down at 0 because there is some hazard of malignant neoplastic disease, even with no occupational exposure. Exposure to radiation is warrant of injury. However, because of the additive, no-threshold theoretical account, more exposure means more hazard, and there is no dosage of radiation so little that it will non hold some consequence.Effects OF RADIATION ON CELLSIonizing radiation absorbed by human tissue has adequate energy to take negatrons from the atoms that make up molecules of the tissue. When the negatron that was shared by the two atoms to organize a molecular bond is dislodged by ionising radiation, the bond is broken and therefore, the molecule falls apart. This is a basic theoretical account for understanding radiation harm. When ionising radiation interacts with cells, it may or may non strike a critical portion of the cell. We consider the chromosomes to be the most critical portion of the cell since they contain the familial information and ins tructions required for the cell to execute its map and to do transcripts of it for reproduction intents. Besides, there are really effectual fix mechanisms at work invariably which fix cellular harm – including chromosome harm.Uses of radiation: Nuclear natural philosophies application are highly widespread in fabrication, medical specialty in biological science, we present a few of these application and implicit in theories back uping them. Tracing: Radioactive tracers are used to track chemicals take parting in assorted reactions. One of the most valuable utilizations of radioactive tracers in medical specialty. For illustration, I, a food needed by the human organic structure, is obtained mostly through consumption of iodinated salt and sea nutrient. Radiation therapy: Radiation causes much harm to quickly spliting cells. Therefore, it is utile in malignant neoplastic disease intervention because tumour cells divide highly quickly. Several mechanisms can be used to present radiation to a tumour. In some instances, a narrow beam of X ray or radiation from a beginning such as 60co is used. In other state of affairs, thin radioactive acerate leafs called seeds are implanted in the cancerous tissue. The radioactive isotope 131I is used to handle malignant neoplastic disease of the thyroid. Black organic structure radiation: An object at any temperature emits electromagnetic moving ridges in the signifier of thermic radiation from its surface. The features of this radiation depend on the temperature and belongingss of the object ‘s surface. Thermal radiation originates from accelerated charged atoms in the atoms near the surface of the object ; those charged atoms emit radiation much as little aerials do. The thermally radiation agitated atoms can hold a distribution of energies, which accounts for the uninterrupted spectrum of radiation emitted by the object. The basic job was in understanding the ascertained distribution of wavelengths in the radiation emitted by a black organic structure. A black organic structure is an ideal system that absorbs all radiation incidents on it. The electromagnetic radiation emitted by the black organic structure is called black body radiation. Radiation harm: Radiation harm means that electromagnetic is all about in the signifier of wireless moving ridges, microwaves, light moving ridges so on. The grade and type of harm depend on several factors, including the type and energy of the radiation and belongingss of the affair. Radiation harm in biological being is chiefly due to ionization effects in cells. A cell ‘s normal operation may be disrupted when extremely reactive ions are formed as the consequence of ionising radiation. Large those of radiation are particularly unsafe because harm to a great figure of molecules in a cell may do to decease. In biological systems, it is common to divide radiation harm in two classs: bodily harm and familial harm. Bodily harm is that associated with any organic structure cell except the generative cells. Bodily harm can take to malignant neoplastic disease or can earnestly change the features of specific being. Familial harm affects merely generative cells. Damage to the cistrons in generative cells can take to faulty cells. It is of import to be the aware of the consequence of nosologies interventions, such as X raies and other signifiers of radiation exposure, and to equilibrate the important benefits of intervention with the detrimental effects. Damage caused by the radiation besides depends on the radiation ‘s perforating power. Alpha particles cause extended harm, but penetrate merely to shoal deepness in a stuff due to strength interaction with other charged atoms. Neutrons do non interact via the electric force and hence penetrate deeper, doing important harm. Gamma beams are high energy photons that can do serve harm, but frequently pass through affair without interactions. For example- a given dosage of alpha atom causes approximately 10 times more biological harm produced by radiation than equal dosage of X raies. The RBE ( comparative biological effectivity ) factor for a given type of radiation is the figure of rads of X ray or gamma radiation that produces the same biological harm as 1-rad of the radiation is being used. Radiation sensors: Atoms go throughing through affair interact with the affair in several ways. The atoms can, for example- ionize atoms, spread from atoms, or be absorbed by atoms. Radiation sensors exploit these interactions to let a measuring of the atom ‘s energy, impulse, or alteration and sometimes the very being of the atom if it is otherwise hard to observe. Assorted devices have been developed for observing radiation. These devices are used for a assortment of intents, including medical diagnosings, radioactive dating measuring, mensurating back land radiation, and mensurating the mass, energy, and impulse of atoms is created in high-energy atomic reaction.Consequence OF RADIATION ON HUMANSA really little sum of ionising radiation could trip malignant neoplastic disease in the long term even though it may take decennaries for the malignant neoplastic disease to look. Ionizing radiation ( x-rays, radon gas, radioactive stuff ) can do leukaemia and thyroid malignant neop lastic disease. There is no uncertainty that radiation can do malignant neoplastic disease, but there still is a inquiry of what degree of radiation it takes to do malignant neoplastic disease. Quickly spliting cells are more susceptible to radiation harm. Examples of radiosensitive cells are blood organizing cells ( bone marrow ) , enteric liner, hair follicles and foetuss. Hence, these develop malignant neoplastic disease foremost. If a individual is exposed to radiation, particularly high dosage, there are predictable alterations in our organic structure that can be measured. The figure of blood cells, the frequence of chromosome aberrances in the blood cells and the sum of radioactive stuff in piss, are illustrations of biomarkers that can bespeak if one is exposured high dosage. If you do non hold early biological alterations indicated by these measurings the radiation exposure will non present an immediate menace to you.Radiation toxic conditionRadiation toxic condition, radiation illness or a crawl dosage, is a signifier of harm to organ tissue caused by inordinate exposure to ionising radiation. The term is by and large used to mention to acute jobs caused by a big dose of radiation in a short period, though this besides has occurred with long term exposure. The clinical name for radiation illness is acute radiation syndrome as described by the CDC A chronic radiation syndrome does be but is really uncomm on ; this has been observed among workers in early Ra beginning production sites and in the early yearss of the Soviet atomic plan. A short exposure can ensue in acute radiation syndrome ; chronic radiation syndrome requires a drawn-out high degree of exposure. Radiation exposure can besides increase the chance of developing some other diseases, chiefly malignant neoplastic disease tumours, and familial harm. These are referred to as the stochastic effects of radiation, and are non included in the term radiation.Radiation ExposureRadiation is energy that travels in the signifier of moving ridges or high-velocity atoms. It occurs of course in sunshine and sound moving ridges. Man-made radiation is used in X-rays atomic arms, atomic power workss and malignant neoplastic disease intervention. If you are exposed to little sums of radiation over a long clip, it raises your hazard of malignant neoplastic disease. It can besides do mutants in your cistrons, which you could go through on to any kids you have after the exposure. A batch of radiation over a short period, such as from a radiation exigency can do Burnss or radiation illness. Symptoms of radiation illness include sickness, failing, hair loss, skin Burnss and decreased organ map. If the exposure is big plenty, it can do premature aging or even decease.

The Significance Of The Title Mythology - 1923 Words

The Significance of the title: Mythology The book that Edith Hamilton wrote, mythology has a title that explains itself. It is a huge book full of mythological animals, people, stories, places, and more. The title mythology is very clever and simple to use because it covers the entire book itself. From the story of the Titans, to Perseus, to Theseus, to Hercules. This book is filled with many adventurous stories of the myths from the Norse, Greek, and roman cultures. The significance of the title is very important and useful too. The title Mythology is like a huge beacon, and people looking for books on mythology know what book to look for. And the title is also important to the book because it is a huge example of foreshadowing too.†¦show more content†¦The external conflict was her struggled with hades as she was taken into the underworld. She was a woman, a goddess of peace and love for the earth, so she didn’t stand a chance against hades. She could only hope for the best, this is an example of man (Woman).vs. Man conflict externally. There is very little that could’ve changed if Persephone had made a different decision, hades still would’ve founder her. If she came with a male god it may have been a little long still she was taken, or if she would’ve seen hades before she could have explained it to Zeus. Basically Persephone had no chance to change her fate, even if she was stronger, faster or smarter, she still will never have the power to beat hades. Maybe if she was more careful, smart, or scared she wouldn’t have eaten any of the seeds. And she wouldn’t have to ever look at hades, but since she ate them we have seasons, and she goes back for four sad and depressing months QUOTES: 1. Hephaestus- Among the perfectly beautiful immortals he was only ugly. He was lame as well. ...........when she saw that he was born deformed, cast him out of heaven†¦..† My connection too this quote of Hephaestus s story is very obvious and easy to spot. Around everyone and even when I’m alone I feel ugly. Like I don’t belong, and like I’m deformed. The book also says that Hephaestus was â€Å"He was