Knowledgement Management Research Paper Example | Topics and Well Written Essays - 500 words

Knowledgement Management - Research Paper Example 1). The meaning of the term knowledge was qualified by Baker, Baker, Thorne, & Dutnell (1997), â€Å"knowledge is present in ideas, judgments, talents, root causes, relationships, perspectives and concepts. Knowledge can be related to customers, products, processes, culture, skills, experiences and know-how† (cited in Kalpic & Bernus, 2006, p. 44). KM is therefore important to the success of the organization because through the collective shared efforts of various stakeholders, the potentials and resources of the organizations are maximized. Core competencies and strengths are capitalized to enable the organization to address risks, threats and changes in external environmental factors that would impinge on the firm’s operations. Accordingly, not only are the organizational objectives achieved; but more so, the relevant contribution of the organization’s stakeholders are thereby percieved as instrumental for the firm’s success and therefore, make each cont ributor better motivated to share their inputs towards a greater good. As noted from Kalpic & Bernus’ (2006) discourse, â€Å"Rouggles (1998), for example, found that the four most common KM projects conducted by organizations were creating/implementing an intranet, knowledge repositories, decision support tools, or groupware to support collaboration† (p. 49). The creation and implementation of an intranet is deemed crucial for organizations to access and connect volumes and diverse information through different departments and functions within the organization. This is an example of KM due to the interplay of inputs, processes and systems that need to be identified, analyzed and connected, as required. Decision-support tools are also examples of KM programs were organizational policies and procedures identify and authorize authorities to decide on significant aspects, alternatives, and options that each personnel, department, or group makes on a daily basis. The design and implementation of

Family Law in America Essay Example | Topics and Well Written Essays - 500 words - 2

Family Law in America - Essay Example In this paper, the case involving Eric and Cindy epitomizes a case whereby spouses are in total agreement until they decide to divorce. Both parties share responsibilities at their home and prior to their marriage, they had signed a prenuptial agreement. The wife disclosed much of her assets and the husband agreed to share the responsibilities at home. Nonetheless, since they have agreed to file a divorce and their case is an uncontested divorce, it looks simple. However, the challenge is that there is no clarity as to whether they have agreed on property division, child custody, and support issues. Since they have agreed to part ways, one of the spouses hires an attorney to prepare the obligatory paperwork. In this case, the wife will only be required to read and sign both the waiver and the final decree. Ethically, it is not possible to represent two parties in a divorce when there is a conflict of interest. If one attorney tries to represent the husband and the wife, in this case, he or she may face some problems. If the attorney takes a side and informs one party that the deal would make it possible for him or her to gain financially, it might anger one party. If the attorney manipulates any party to decide otherwise, the case is considered unethical. In fact, one attorney cannot represent two parties with conflict of interest. Getting an annulment is out of questions because it is a court order that a marriage never existed. Annulment could only be granted if the spouse was already married to someone else. Annulments are very rare. In this case, there is no such a case whereby the husband is claimed to have been married to someone else. However, the case indicates that the wife had mental issues, but still the issues never avoided her from agreeing to marry. She was not forced to marry, they all agreed. Annulment, in this case, is not appropriate because after realizing that the wife had mental problems, the husband was willing to continue with the married out of love.

Properties of Dopamine in Chemistry

Properties of Dopamine in Chemistry Chapter 2. Literature Review 2.1 Introduction In recent years, natural adhesion has attracted increasing attention in the material engineering field. This can be mainly attributed to the marine mussel as it has a strong ability to attach to various surfaces in an aqueous environment where they reside. These surfaces vary from natural to synthetic, and inorganic to organic.[49-51] Previous studies on the mussel adhesive protein have discovered that 3,4-dihydroxy-L-phenylalanine-lysine sequences, may be the main contributor for the versatile nature of the marine mussel.[52, 53] Dopamine, having a similar structure with this sequence, may provide a new platform for bioengineers to physically or chemically enhance the performance of other biomaterials. Several papers have already been published regarding the use of dopamine to augment other biomaterials, such as poly (ethylene glycol), carbon nanotubes and nanofibers. The first part of this review will briefly introduce the basic properties of dopamine which will be followed by its applications 2.2 Properties of Dopamine Dopamine’s properties can be divided into chemical and adhesive properties. The chemical properties mainly focus on the autopolymerization in aerated basic solutions and polymerization of dopamine based on vinyl groups. The adhesive property is dopamine’s most significant feature which gives dopamine its advantage as a biomaterial. 2.2.1 Chemical Properties 2.2.1.1 Autopolymerization in Aerated Basic Solutions Messersmith and coworkers first reported that dopamine is able to auto-polymerize in aired Tris buffer of pH 8.5.[8]. The process of dopamine autopolymerization with a pre-existing substrate results in polydopamine (PDA) films being deposited on the substrate surface. Longer substrate exposure times and higher reaction temperatures result in thicker PDA films being formed.[54] Regardless of the surface type, the inserted PDA films can be coated on the desired surface, even poly(tetrafluoroethylene) (PTFE), known for its anti-adhesive property.[8] 2.2.1.2 Polymerization of Dopamine Based on Vinyl Groups Polymers carrying pendant dopamine are normally obtained by radical polymerization of vinyl monomers with protected or unprotected dopamine. When meditating protected dopamine carried by polymers with double bone, borax (Na2B4O7 ·10H2O) is widely used as the protecting reactant in order to keep dopamine from forming an annular bidentate catechol subunit.[55] Normally, the polymerized reaction of protected dopamine happens in a liquid solution and forms linear chains. Deprotection reaction usually occurs in an acidic environment and results in the polymer carrying dopamine. Dimolybdenum trioxide[56], 1-dromotoluene[57] and denzophenone chloride[58] can also be used as protecting agents. Zhang et al.[59] designed a novel polymer poly (n-acryloyl dopamine) that possesses high adhesion to wood, especially when mixed with polyethylenimine (PEI) at about 150 °C. They used a protected double bond dopamine as a monomer and 2,2’-azobis(2-methylpropionitrile) as an initiator via rad ical polymerization, following the deprotection of dopamine in an acid solution. When meditating unprotected dopamine, Lee BP et al.[60] was the first to report a creative hydrogel that copolymerizes modified dopamine with double bond and polyethylene glycol diacrylate via photo initiation by using a 2,20-dimethoxy-2-phenyl-acetonephenone (DMPA) initiator. As a result of this invention, greater attention has been given to hydrogels as a new artificial extracellular matrix (ECM) in the biomedical field. Dopamine belongs to the catechol family which leads to vinyled dopamine to act as an inhibitor.[61, 62], as a result they can react with radicals to inhibit polyreaction. The unprotected dopamine, modified with a vinyl group, is able to undergo free-radical polymerization. Several researches have done this experiment on radical polymerization to prove the reliability of this method.[63-75] The research group led by Metin Sitti, copolymerized a dopamine derivate (dopamine meth-acrylami de) with methoxyethylaceylate to obtain a reversible adhesion on the surface of nonflat glass under dry or wet condition.[65] In another publication, 2-(meth-acryloyloxy) ethyl phosphate was used to copolymerize with dopamine methacrylamide, followed by a complicated cohesion in which the copolymer bonded with positively charged polymer, divalent calcium and magnesium.[71] The chemical properties of dopamine provide the platform of its strong adhesive properties. 2.2.2 Adhesive Property The adhesive property of dopamine is one of the most significant properties of dopamine as it has proved to be very versatile in adhering to various surfaces despite the surface chemistry. The bonding between dopamine and surfaces can be generally distributed to two parts: covalent and non-covalent.[10] Surfaces which possess amine groups or thiol groups can covalently bind to dopamine via Michael addition or Schiff base reactions. However since most surfaces don’t have those groups, non-covalent bonding, like H-bond, Ï€-Ï€ interaction and benzenediolcharge-transfer compounds are preferred to generate a valid layer and metallic chelating.[7, 53, 76-87] In a high pH environment, metal ions and medal oxides have a high chance of being hydroxylated or hydrated, which make chelate with catechol groups of dopamine much easier. This can be seen from many experiments done on polydopamine linking with metal oxides (such as Fe2O3, Fe4O3, ZrO2) through chelating bonding interaction.[82, 84, 85] This can be seen when polydopamine nanoparticle suspensions are added to a solution of KMnO4 with H2SO4. A core-shell nanoparticle structure is created in which the polydopamine act as the core and MnO2 act as shell, followed by blending the KOH solution to obtain MnO2 nanospheres. This ad hesive property of dopamine provides promising opportunities for new bioengineered materials. 2.2.3 CNT For decades, carbon nanotubes (CNT) have been attracting increasing attention because of their superior features, such as thermal conductivity, excellent tensile strength and remarkable conductivity. They have been applied in various different areas, from sensors to catalysis, and from semiconductors to inductors for osteocytes. In order for CNTs to have a wide range of applications, surface modification is necessary. However, during this modification various intermediate reactions steps are required which increase the complexity of the CNT’s fabrication. Dopamine modification has been viewed as an promising alternative, leading to a coated multifunctional CNT with a polymeric shell that has tunable thickness by time, pH value and temperature.[88] The dopamine coating facilitates the addition of alternate modifications to the surface of CNTs, such as gold nanoparticles.[88] What’s more, CNTPDAs, first, were modified with ATRP initiator and then polymerized with diethyla mine methacrylateto to form brushes polymer — poly (dimethylamine-thyl methacrylate) (PDMAEMA) on the surface.[89] Following that the functionalized CNT were quaternized in order to combine palladium nanoparticles on the CNTs’ surface. These two examples indicate the capability of dopamine coated CNTs to bind to metal complexes. 2.3 Applications There are many different applications in which dopamine could be applied in; three of them will be the focus here including applications in hydrogels, nanofibers, and biosening. These fields are of great interest currently as they show great promise for dopamine in bioengineering. 2.3.1 Hydrogel The need of a viscous hydrogel, as a unique material, is dramatically increasing in various biomedical fields. The high performance requirements of adhesive hydrogels are strict and various. This includes being sufficiently adhesive in a wet environment, satisfactory elasticity of artificial tissue scaffold and biocompatible.[60, 90] Moreover, biomedical hydrogels also need a quick sol-gel conversion for avoiding surgical obstruction. Recently, adhesive hydrogel, inspired by strong wet adhesion of mussel and cross-bonding capabilities of dopamine, has been attracted increasing attention and considered as a hopeful candidate to fulfill this technologic niche.[91] Messersmith et al.[92] reported the creation of four different adhesive hydrogels using dopamine derivative (L-3,4-dihydroxyphenylalanine (DOPA)) as end-groups and poly(ethylene glycol) (PEG) as a backbone. The difference of these four hydrogels can be divided into 2 subcategories, linear network and branched network. They applied multiple-angle laser light scattering to study the influences of different oxidative reagents on DOPA oxidation and hydrogel formation. The result showed that gelation time of PEG-DOPA gels relied on oxidative reagents, such as concentration and type. In Lee H.’s report, they also used DOPA and PEG to form hydrogels, but this time they used DOPA modified with methacryloyl chloride and PEG diacrylate instead of pure DOPA and PEG. In order to avoid introducing toxicity of oxidative reagent to the hydrogels and any loss of adhesion, the hydrogels underwent UV initiation.[60] These photo-imitated gels demonstrate appreciable elastic properties for use as a promising biomedical material. Using a similar method Phillip B. Messersmith’s research group also synthesized an adhesive hydrogel, prepared by copolymerizing DOPA with hydrophobic segments of an amphiphilic block copolymer under photo-imitation. The adhesive property of the hydrogel was surprisingly improved in the presence of DOPA in wet condition. The elasticity of the hydrogel was found to be similar to that of soft tissues leading to consider it as a encouraging candidate for biomaterial.[93] Further research conducted by Messersmith and coworkers focused on the biological capabilities of dopamine-PEG adhesive gels. In 2010 they reported that DOPA as end-caps covalently bonded with an amine-terminated 4-arm PEG. The PEG was the core in which oxidative reagents (NaIO4) were added to form an adhesive hydrogel in less than 1 minute.[94] The results of the in vivo test, performed in a murine model, showed the adhesive gels caused minimal inflammation and were stably interfaced with the surrounding tissues for more than 24 months. To form a catena degradable adhering polymer, three materials were reacted to form a semblable branched polymer, including dopamine derivative as end-group, PEG and polycaprolactone (PCL) as a backbone.[95] These polymers are able to form films whose properties, such as swelling capacity and biodegradation, were flexible by changing the ratio, or concentration of these reactants or by adding other additive agents. After coating these adhesive polymer s on a biologic meshes, stronger water-resistant was exhibited when compared with fibrin sealant or cyanoacrylated polymers.[95] Applications for this biomaterial can be extended in the surgical field for hernia repair. Stewart’s group published several papers about adhesive hydrogels based on complex cohesion. In 2010 they created a bio-mimic hydrogel blending with revised gelatin and a copolymer which is obtained by a dopamine derivative reacting with monoacryloxyethyl phosphate in an alkaline condition.[71] The addition of Ca2+ and Mg2+ to the bio-mimic hydrogel could significantly improve the coacervation of the hydrogel, which was applied to tune agglomeration temperature to body temperature. The result demonstrated that the cohesion interaction was biodegradable, perfectly suited for medical applications. In another similar research, an adhesive hydrogel was synthesized by complicated cohesion of a positively charged copolymer and a terpolymer involving a dopamine derivative when its pH was higher than 4.[70] The bonding property of the hydrogel to hydroxylapatite was around 40% of common cyanoacrylate glue. T.G. Park’s group developed a temperature sensitive and injectable tissu e-attachable hydrogel.[96] The hydrogel was synthesized by conjugating hyaluronic acid and dopamine, following by cross-linking with thiol tail-ended Pluronic F127 via Michael addition. The hydrogel precursor exists at room temperature, and a cured hydrogel is formed when brought to a temperature of 37 °C. In a later paper, they used a similar strategy forming hydrogel by blending a dopamine derivative modified chitosan with thiol-capped Pluronic F127 at body temperature.[97] The adjustable gelation time of this block copolymer made it suitable for tissue-repair at 37 °C. The resulting hydrogel dedicated excellent in vivo results, where chitosan served as hemostatic agent and dopamine derivative group acted as adhesive agent to soft tissues. 2.3.2 Nanofiber Tissue engineering tends to use nanofiberous biomaterials instead of a micropores matrix since the filiform and polyporous nanolevel structure allow for artificial extracellular matrix to enhance the fundamental cellular procedures.[98] Nanotechnology reformation have aided in the development of techniques for the production of such a nano-composite materials. Electro-spinning has recently obtained increasing attention, attributing to its briefness and facility for nanofiber fabrication. Through this technique, fibrous structures are easily tuned in order to coordinate it with the extracellular matrix (ECM).[99, 100] So far, this technique has been studied in a range of biological fields, such as bone and skin regeneration. The artificial polymer ECMs usually have difficulties with interfaced reactions between tissues and materials.[101] For electro-spinning nanofibers in applications of biomedicine, it is necessary to physically and chemically combine them with biomolecules or cell-recognizing ligands.[102] This subsequently provides bio-modulating or biomimetic micro- environments to contacting cells and tissues. Dopamine coating can be considered as a simple and versatile approach to modify various synthetic polymers so that they are able to serve in biomedical applications.[49-51] Ku and coworkers[103] firstly reported culturing human endothelial cells on a polydopamine treated electro-spun polycaprolactone (PCL) nanofiber membrane. They used two control groups, pure PCL nanofibers and PCL nanofibers coated with gelatin, to investigate the ability of cell attachment of dopamine. The result of the water contact angle demonstrated that polydopamine uniformly was coated on the PCL nanofibers. Polydopam ine also significantly improve endothelial cells’ attachment on the nanofiber, compared with other non-adhesive substrates. Moreover, endothelial cells culture on PCL nanofibers coated by dopamine had developed cytoskeleton, positive PECAM-1 and vWF expressions and high cell extend.Rim and coworkers[104] designed dopamine functionalized electro-spinning poly(L-lactide) (PLLA) nanofibers with minimal influence on its mechanical performances, like wetting capability and roughness. The polydopamine coated PLLA nanofibers significantly enhanced cell attachment and the degree of spread, contradistinguishing with pure PLLA nanofibers. Meanwhile, its fibrous morphology had changed to more of a polygon shape instead of sphere after the polydopamine coating, which lead to higher DNA content of polydopamine treated PLLA nanofibers. The higher gene expressions of cells cultivated on polydopamine treated fibers indicated better osteogenic differentiation and vasculogenesis. Extensive research regarding the chemical or physical coating of metal on the surface of scaffolds to increase tensile strength has been done.[105] Jungki Ryu et al.[106] used dopamine to process hydroxyapatite deposits on PCL nanofiber by coating it. The result demonstrated a combination of surface activation through dopamine coating and hydroxyapatite mineralization allowing the hybridization of various shapes and surfaces. In other reported, Xie and coworkers[107] considered dopamine as a ‘superglue’, allowing minerals to easily attach to fibrous surfaces. The mechanical properties of mineral functionalized electro-pinning PCL nanofibers, such as stiffness, durability and tensile strength, were near to that of natural bone. Dopamine coated nanofibers show an improvement on existed biomaterials such as their mechanical performances, and cell adhesion. This makes them quite suitable for tissue regeneration and other related bioengineering applications. 2.3.3 Biosensing There is an enormous demand to design highly sensitive and selective biosensors for multiple applications, such as diagnostics, drug screening, and drug discovery.[108] Biosensors usually are in the microscale or nanoscale[109] and there are numerous methods to develop them, such as DNA[110] and antibody-based sensor[111, 112]. Scientists employ dopamine in order to optimize biosensor’s capabilities which have been reported by several research groups. Lui and coworkers first reported that dopamine could be used in a biosensor.[113] They used electricity to oxidize dopamine to form polydopamine on a gold electric pole with existing nicotine. The dopamine-imprinted sensor showed outstanding selectiveness of nicotine and excellent repeatability. Furthermore, Ouyang and coworkers developed a one-step well-defined structure of a dopamine-imprinted sensor.[114] They applied electro-polymerization of o-phenylenediamine (o-PD) and dopamine with existing glutamic acid (Glu). By using a potentiostatic time scan, the sensor exhibited satisfactory stereo selectiveness of bonding L- or D-Glu because their relative synthetic receptor. In a different publication, they designed protein imprinted nanowires which dopamine was also involved.[115] First, the protein-coupled alumina membrane was immersed in dopamine solution followed by an ammonium persulfate solution in order to self-polymerize polydopamine; in which afterward the removal of the atta ched protein is necessary. The nanowires demonstrated constant bonding capability and selectiveness of template proteins due to their cavity structure with bonding spots (like amino group, hydroxyl, Ï€-Ï€ stacking and van der Waals force) that can bind with protein. In another research, Zhou et al. display the creation of magnetic nanoparticles coated by imprinted polymer with a pre-existing template protein.[116] The nanoparticles are able to separate target protein from the mixture. In order to investigate the versatility of the imprinted nanoparticles, they operated on a binding test by using five different proteins excluding the template protein. The result indicated that more than 80% of target proteins were rebinding with imprinted nanoparticles, suggesting imprinted nanoparticles have a bright future to be employed for separating and detecting specific protein. One of the greatest difficulties for biosensors is how to immobilize enzymes on the surface of an electric pole and preserve the enzymes’ functionalities. Wei et al. designed a novel glucose electrochemical sensor, prepared by using a polydopamine film to entrap glucose oxidase and gold nanoparticles.[117] Their research displayed a polydopamine matrix embedded with gold nanoparticles that had high efficiency of immobilizing glucose oxidase. The dopamine film embedded gold nanoparticle biosensor showed a superior sensitivity, good repeatability, linear over broad dynamic range and a low detective threshold. Furthermore, in order to assess adaptability of this sensor, they use it to test glucose concentration in attenuated human serum. The result suggested this biosensor is an attractive material for clinical applications

Utopia Essay -- More Philosophy Perfect Society Essays

Utopia The text Utopia was written by Sir Thomas Moore in 1516, just before the outbreak of the Reformation. More’s life flourished through the late fifteenth and early sixteenth centuries, which were influential years in the Renaissance, a flowering of art and thought that began in Italy and flooded through Europe and England. Humanists often stressed the dignity of man and the power of reason while remaining deeply committed to Christianity. Their thought and writings helped to break the strict religious orthodoxy that had forced itself through the Middle Ages. Humanists often argued against feudalism as it promoted a society dominated by the rich and unfair on everyone else. Further, they saw feudal society as irrational. Utopia was originally written in Latin, is a text that depicts what is claimed to be an ‘ideal’ human society through the eyes of the narrator Raphael Hythloday. It is also largely based on the voyages of More himself, specifically to the Netherlands. It was one such voyage — a diplomatic mission from England — that More invented his ideas about a Utopian society. However, while More may have visualized the Utopian Islands as a perfect society, it is inarguable that the utilitarian society of Utopia was a criticism of the European world he saw around him. Thus, it is important for the readers to understand and respond to the specific time. There are many ways to view the utopian society; some may view it as the result of rational thought or Humanist beliefs, others as an alternative to feudalism, a statement in favour of communal society, or an effort to promote reform according to Christian values. The book Utopia is composed of two parts – the first written last, and the second written first. The second book is the one in which the utopian society is portrayed and the issues raised closely represents the thinking of humanist Erasmus. The first part of the novel serves as an introduction to the two main fictional characters of the novel – More and Hythloday. It debates reasoning as well as social critique. Hythloday cannot stand the inequalities and injustices on the existing England and Europe and reveals possibilities for reform using his example of a Utopian society. The second part is written through the eyes of Hythloday and his explanation of the Utopian society of More. It serves as an improvement for wher... ...hey do nothing in return but forgive seems highly unfair, and demonstrates an assumption of superiority in the men. Given the gender situation in the sixteenth century under which women were subservient to first their father, then their husband. However, women in Utopia can become priests, and this would have been a shift from More's generation. Even in modern society, the Catholic Church does not allow female priests. This is one example where Utopia implies the ignorance of gender, offering females a chance at equality. Utopia is a depiction of a semi-ideal society and all of the criticism of European society that ideal represents, and it is a explanation on itself and its themes. The book can at times be inconsistent, just as More himself could: a man who preached religious toleration and logically mistreated Protestants, decides to remain a Christian rather than enter the priesthood but ultimately died a willing victim for his faith. Ultimately, Utopia is a book that, like More, attempted to navigate a course through the ideal and the real, between a want to create perfection and the practical understanding that perfection, given the imperfection of mankind, is impossible.

Reasons for inefficiency in monopolies Essay

1 Reasons for inefficiency in monopolies 1. 1 Monopolies and pricing A monopoly prices its products where marginal costs meet marginal revenues to maximise profits. Due to the fact that this price is higher than the market price in perfect competition, many consumers are not able or willing to buy at the higher price. This deadweight loss is an allocative inefficiency. Figure 1: Pricing in monopolies and perfect competition The consumer surplus in perfect competition is 1+2+4, and the producer surplus is 3+5. The consumer surplus in a monopoly is 1, the producer surplus is 2+3, and the deadweight loss is 4+5. 1. 2 Monopolies and productive efficiency In theory, a monopoly does not have to be less (productive) efficient than perfect competition. In reality, however, almost all monopolies tend to be inefficient. This may be for the following reasons: 1. 2. 1 Pressure for productive efficiency In perfect competition the price within an industry is determined by the market, or in other words, by demand and supply. Profit maximisation is achieved where the marginal cost curve intersects the demand curve (see figure 1). This means that in perfect competition, the company maximises its profit at the minimum point of its average cost curve. A company in a perfectly competitive environment tries, therefore, to be as efficient as possible in order to meet the minimum average cost. This causes a lot of pressure to achieve productive efficiency. A company in a monopolistic environment is able to change not only its cost, but also its prices. There is far less pressure for productive efficiency. 1. 2. 2 Diseconomies of scale A monopoly may increase its output to the point where it exceeds the minimum point of cost on its long-run average total cost curve. In this case, diseconomies of scale occur. 1. 2. 3 X-inefficiency. In perfect competition, X-inefficiency of one market participant will have almost no influence on the market and the market price. X-inefficiencies in a monopoly increase cost and, therefore, price. X-inefficiencies are more likely in monopolies because there is no benchmark to monitor the performance of management and less pressure from shareholders and markets. 1. 2. 4 Principal Agent There are no benchmarks and most shareholders and regulators do not have the insight into the company to evaluate management. 1. 2. 5 Case study: Deutsche Post AG (DPAG), Germany. The privatisation of most regulatory monopolies during the last few decades shows that competition decreases costs: Figure 2: Deutsche Post AG: Postal items delivered and employees (FTE) 1999-2005 The Deutsche Post AG lost its monopoly on the delivery of letters over 100 grams in 1998 and on the delivery of letters between 50-100 grams in 2005. From 1999- 2005, employees were reduced by 16% despite the fact that the total number of items delivered increased by over 3%. This means that during the monopoly the DPAG had a lower productive efficiency, delivering fewer items with more people and higher costs.

10 years from now Essay

I don’t like thinking too much about the future, I’ve always been one to worry. Despite all the what-ifs that go through my head on the daily, I try to remember that there are certain things that I can control and many things that I can’t. I am learning how to focus on those things I can control in order to create a successful life for myself. In ten years from now I will be 28 years old and everything else is just a fantasy. I plan on finishing two years of pre-requisite classes at Kirkwood and then continuing on to Mount Mercy University to study nursing and earn my BSN (Bachelors in Nursing). I will be finished with school so with that being said I see myself as a nurse working in a hospital, that is if I don’t change my major five times before I graduate. Read more:Â  10 Years From Now Essay By almost 30, I hope that I will be close to married and preparing myself to start a family. I’m not sure how many kids I plan on having, but probably no more than three. I plan on being financially comfortable which includes owning my own car and home. I know through out my life I will always continue to be close with my family, so I’m hoping that I always live in close distance of my parents and my sister. When it comes to planning out ten years from now I feel as though I have a good grasp on which road I’ll be going down, but that road could be going many different directions. I plan on taking it one day at a time, and hopefully with that strategy by the time I’m 28 I will be a very happy woman. 10 Years From Now Essay Ten years ago, I was in middle school, and was a kid that only wanted to do homework after school, eat, watch television and play with friends. I was a kid that did not care about the future and, if you had asked me what I wanted to be, I would have simply answered that someday, I will be a racecar driver. Now, I am able to clearly imagine the position I want to be in ten years. In ten years, I will have completed my bachelor’s degree in Bussiness administration major in financial management. After my graduation at dlsl, I would have gotten a good entry-level job in the financial industry We are thinking too much. It seems odd at first, but the only way that you’ll be proud of yourself ten years from now is to stop thinking about time and to start focusing on the now. see more:where i see myself in 5 years essay