donot use Ai at all. this is a personal essay to get into nursing school . prompt is why nursing at hunter college
Author: admin
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vital signs
Submit a research paper regarding vital signs with all considerations See Rubric bellow Include the following components in your research paper: 1. Title Page 2. Introduction (general) 3. Mention research studies (at least three articles) that validate the information presented in your paper. (Publication date should be no more than five (5) years old). 4. Conclusion 5. References Page 6. Do an article review relate to vital signs and present a brief summary -
discussion Still Alice
In the film Still Alice by Lisa Genova, we see Alice plans for the future while she still possesses the ability to plan, but she doesnt plan well enough. She sees AD as a memory-robber that interferes with language abilities and memory (which is mostly true). She sets up memory tests on her phone to show when her illness has run its course and when it is time to take her own life. Early on, she plants pills in a safe place with the intent to overdose. However, she does not foresee being interrupted during her attempt to carry out her plan, as she attempts to open the bottle the pills spill out and roll onto the floor as her caregiver enters the home. She is still alive (and still Alice) before the film ends. Eerily, the words Alice and alive are easy to interchange when typing, because c is next to v on her phone, making me curious if this could actually happen making her change her mind.
(a) In saying all of that, do you think the plan Alice constructed was a viable one? Think about quality of life; both Alice and her family. Is this decision in character for Alice? Do you think her family would have understood or approved?
(b) Do you think the film rendered enough of how the family felt about the disease, about Alice, and their plans to take care of her?
2. The crisis is presented in the title.
(a) Is she still Alice?
(b) Despite all the agony, the fear and the indignity of Alzheimers, is there some unbreachable core of identity that will remain? Or is Alices sense of self utterly eroded, reduced to merely a set of symptoms?
3. Do you find irony in the fact that Alice, a professor and researcher at Columbia, suffers from a disease that causes her brain to atrophy?
(b) Why do you think the film maker chose this profession?
(c) How does her past academic success affect Alice’s ability, and her family’s, to cope with Alzheimer’s Disease?
4. When Alice’s three children, Anna, Tom and Lydia, find out they can be tested for the genetic mutation that causes Alzheimer’s, only Lydia decides she doesn’t want to know.
(a) Why does she decline?
(b) Would you want to know if you had the gene?
5. Alice asks John to take a sabbatical year together.
(a) Why does John decide to keep working?
(b) Is it fair for him to seek the job in a new state considering Alice probably won’t know her whereabouts by the time they move?
(c) Is he correct when he tells the children she would not want him to sacrifice his work?
6. The film is primarily told from Alice’s point of view. As Alice’s disease worsens, her perceptions indeed get less reliable.
(a) Why would the film maker choose to stay in Alice’s perspective?
(b) What do we gain, and what do we lose?
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why nursing at hunter college
donot use Ai at all. this is a personal essay to get into nursing school . prompt is why nursing at hunter college
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IRB
The next step is for you to submit the documents outlined below.
Given the responses you provided, it appears you will be following the . Is that accurate? If so, then we will also need a draft of your invitation (using the template in appendix B in the manual), a draft of your consent form (using the template in appendix C in the manual), and a copy of your human subjects protection training completion certificate, please (see additional instructions at the end of this email).
Please note, attached to this email is a copy of your Form A. Should you need to make any changes to the information in Form A, please update this Word document version with those revisions.
Alternatively, if you prefer not to follow this manual, please reply to this email to confirm, and we can provide guidance on your next steps.
If you are following the , please email your documents (as attachments) directly to , once your committee chair has approved for your to do so. Please ensure that your committee chair is CCd on this submission (and all future submissions).
If you have any questions about what is needed for the next step in this review process you may email those to .
If you have not yet completed the CITI training, when you access the site you will need to Register for an account. You will be asked to Select Your Organization Affiliation and you should enter Walden University. Then follow the steps to complete your registration.
**Note: If you have taken the NIH training and have a copy of that certificate, you are welcome to submit that document instead. However, as of September 27, 2018, the NIH website ceased offering their training and provided no option to download previous completion certificates from their site.
Sincerely,
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Leveraging AI in organizations
Hello, I have to write a research proposal and literature review. My topic is leveraging AI in organizations. For this assignment, I leveraged 10 articles, these articles are added as attached materials. Also, see below for what the assignment needs you to do.
Assignment requirement:
Mini-Research Proposal: Introduction Background information on the research topic Statement of the research problem Research questions Significance of the study
Literature Review A brief review of existing literature related to your research topic Theoretical framework or key concepts guiding your research Identification of gaps in the literature Research Design and Methodology Qualitative or Quantitative Data collection methods (e.g., surveys, interviews, experiments) Gaps and Limitations References, formatted in APA 7th edition.
I request and emphasize no plagiarism or AI detection. Please strictly no AI use. Thank you.
Attached Files (PDF/DOCX): Adoption_of_Artificial_Intelli.pdf, The_dark_side_of_artificial_in.pdf, Generative_AI_adoption_and_emp.pdf, Prioritizing_challenges_in_AI_.pdf, A_conceptual_framework_for_AI_.pdf, Exploring_the_challenges_of_AI.pdf, Modeling_the_Drivers_of_Blockc.pdf, AI-Enabled_Strategic_Transform.pdf, The_mental_health_implications.pdf, Stupid_to_Smart_The_Sustainab.pdf
Note: Content extraction from these files is restricted, please review them manually.
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chem exp 2
Experiment 2. Molecular Geometry and Polarity
Objective:-
To draw Lewis structures and use the Valence Shell Electron Pair Repulsion
(VSEPR) theory to predict the molecular geometries of molecules and polyatomic
ions.
To predict polarity of molecules and ions.
BACKGROUND
Large-sized models of molecules are used to represent particles that are too
small to see with the human eye. These macro-sized models are useful for visualizing
the physical arrangements of atoms in molecules and polyatomic ions and aid in
understanding properties, such as the polarity of some small molecules and the
reactivity and interaction of atoms in molecules. Molecular models are ball and stick
sets in which each ball of a different color represents atoms of a different element.
A basic concept of the atomic theory is that the chemical and physical properties
of a substance are determined by the distribution of outermost shell electrons in its
atoms and by the spatial arrangement of these atoms in the structure of the substance.
Lewis Dot formulas are two dimensional representations that use the arrangement of
outer shell electrons to give basic information on the three dimensional arrangement of
atoms in molecules and polyatomic ions.
Experimental techniques such as x-ray or neutron diffraction in crystals, infrared,
Raman and microwave spectroscopy, and dipole measurements provide information on
the relative positions or geometric arrangement of atoms in real molecules and in
polyatomic ions. Experimental data on shapes and polarity agree very closely with
shapes and polarity predicted from models for simple molecules and polyatomic ions.
The following rules and procedures are given as a guide in drawing Lewis
Electron Dot Formulas.
Drawing Lewis Structures
Rule 1. For small molecules and polyatomic ions, place the element with the lowest
electronegativity in the center and arrange the more electronegative atoms around it.
Note:- Hydrogen should not be used as a central atom.
2
Oxygen atoms do not bond to each other except in O2 (dioxygen), O3 (ozone),
O22- (peroxide ion), and O2- (superperoxide ion).
Rule 2. In oxyacids such as HNO3 and H2SO4, hydrogen atoms are usually bonded to
oxygen atoms which in turn are bonded to the central atom.
Arrangement of Electron Dots:-
Count the total number of valence electrons from all atoms in the formula,
including electrons due to negative charge, if any.
Arrange atoms around the central atom; remember to apply Rule 2.
Two electrons are used to form a bond.
Complete the octets of the atoms attached to the central atom; remember that
hydrogen can accommodate only 2 electrons.
Put any remaining electrons on the central atom to satisfy its octet. These extra
electrons are shown as pairs.
If the central atom has less than an octet, form double or triple bonds with the
surrounding atoms.
There are compounds which are exceptions to the octet rule. For instance, in
BF3 the central atom has less than 8 electrons. Such species are called electron-
deficient molecules. On the other hand, the central atoms in PCl5, SF6, IF5, etc.
Elements in the third row of the periodic table and beyond often exhibit expanded octets
of up to 12 electrons.
Electron-Domain Geometry (Electronic Geometry)
The VSEPR Theory states that shared (bonding) and unshared (nonbonding) electron
pair domains around the central atom arrange themselves as far apart as possible. In
other words, electron domains will orient themselves so as to minimize the repulsion
between them. Electron pairs used to form multiple bonds (i.e. double or triple bonds)
are counted as one electron domain. Electron pairs used to form single bonds are
counted as electron domains.
Example. What is the number of electron domains around the central atom in CO32-?
3
O
C
O
O
2-
The three electron domains in CO32- arrange themselves so as to minimize repulsion
with each other. In other words, the electron domains occupy three regions around the
carbon atom forming a trigonal planar geometry.
Molecular Geometry (Molecular Shape)
Molecular geometry refers to the relative positions of the atoms around a central atom of
a molecule or polyatomic ion. Molecular geometry of a molecule is determined by how
the surrounding atoms are arranged around the central atom, which is in turn determined
by how the electron domains are arranged around the central atom. The following link
can be used to determine the electronic and molecular geometries of simple molecules:
https://billvining.com/mmlib_sims/#gen_8_2.
Molecular Polarity (Dipole Moment)
In polyatomic molecules/ions, the presence of polar bonds may or may not result in a
polar molecule, depending on the molecular geometry. If the molecular geometry of a
molecule/polyatomic ion is completely symmetrical, the molecule/polyatomic ion is
nonpolar. In other words, in a totally symmetric molecule individual bond dipoles cancel
each other completely (i.e. the net dipole moment is zero). If the molecular geometry is
not totally symmetric, the molecule has a net dipole moment and hence is polar. Polarity
influences both physical and chemical properties of molecules. A molecule is nonpolar
regardless of its geometry, if it does not contain polar bonds. An individual bond is polar
if the two bonding atoms have sufficiently different electronegativities.
_
There are three electron domains around C atom:
i.e. two single bonds, counted as two electron domains
and one double bond counted as one electron domain.
4
Name: _______________________ Date: _______________
CHM 114
PROCEDURE
i) Watch the lab recording posted on Canvas along with the lab handout.
Predict the molecular geometry and polarity of the molecules/ions listed in
Table 3.
ii) Draw the Lewis structures of the molecules/ions in the space provided in the
table and state the molecular geometry (shape).
iii) Check if the geometries you predicted are correct using the following
simulation: https://billvining.com/mmlib_sims/#gen_8_2.
iv) Predict the polarity of the molecules/ions based on their geometries.
Table 1. Lewis structure, molecular geometry and polarity of selected molecules
and ions.
Molecule
/Ion
Lewis Structure
Name of
Molecular
Geometry
Polar or
Nonpolar?
XeF4
PCl3
Molecular geometry and polarity
5
Table 1 continued ………..
IF4-
OF2
SF4
SeF6
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Interview a Nurse
Instructions:
The objective of this paper is to introduce you to a nurse and discover what motivated them to become a nurse and obtain trends in nursing that influence nursing care today. This will give you an opportunity to explore other questions you may have in addition to the recommended questions.
Identify a nurse, the nurse may be a relative, close friend, or acquaintance. Interview this person and answer the following questions.
- Why did they become a nurse?
- Who are their heroes and/or role models? Why?
- What has nursing given to them in their personal and professional life?
- What do they believe caring means?
- What do they believe contributes to a caring professional nurse?
- How have they observed changes in nurses over the years?
- How do they see the future of nursing?
- What words of wisdom do they want you to know?
Submission Instructions:
- Submit a 600 word count Word document (.docx), APA formated paper, with a cover page.
- Do not use full name of the person you interview to protect privacy (use initials or may use another name)
- Submit work via Turnitin assignment by 11:59 PM CST Sunday.
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Translate the Evidence
The next steps in the evidence-based practice (EBP) process include implementing and translating the intervention chosen in the PICOT question (Week 1) into the clinical setting. Pilot projects are often used before implementing a change into an entire organization. Discuss the following questions related to implementing the chosen PICOT intervention as if a pilot test project were being facilitated by the experts prepared nurse:
PICOT question- In patients with chronic kidney disease (CKD), how does early Nurse Practitioner-led education compared to usual care affect disease progression over 12 months?
Assignment Criteria:
- Briefly explain the problem and the PICOT question and the intervention
- Describe the pilot project for the chosen intervention and include:
- Explain the who, what, where when and how of the pilot project
- Describe a specific model or framework of change that will be used to facilitate the implementation of the intervention.
- Describe the stakeholders and their roles in the pilot project.
- Propose two (2) strategies that would promote engagement of the stakeholders in the project.
- Discuss a specific practice guideline that supports the intervention.
- Identify major organizational resources needed for the pilot project.
- Discuss how the outcome of the intervention will be measured.
- The scholarly paper should be in narrative format, 5 to 6 pages excluding the title and reference page.
- Include an introductory paragraph, purpose statement, and a conclusion.
- Include level 1 and 2 headings to organize the paper.
- Write the paper in third person, not first person (meaning do not use we or I) and in a scholarly manner. To clarify: I, we, you, me, our may is not used. In addition, describing yourself as the researcher or the author should not be used.
- Include a minimum of four (4) professional peer-reviewed scholarly journal references to support the paper (review in Ulrich Periodical Directory) and be less than five (5) years old.
- APA format is required (attention to spelling/grammar, a title page, a reference page, and in-text citations).
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chem exp 2
Experiment 2. Molecular Geometry and Polarity
Objective:-
To draw Lewis structures and use the Valence Shell Electron Pair Repulsion
(VSEPR) theory to predict the molecular geometries of molecules and polyatomic
ions.
To predict polarity of molecules and ions.
BACKGROUND
Large-sized models of molecules are used to represent particles that are too
small to see with the human eye. These macro-sized models are useful for visualizing
the physical arrangements of atoms in molecules and polyatomic ions and aid in
understanding properties, such as the polarity of some small molecules and the
reactivity and interaction of atoms in molecules. Molecular models are ball and stick
sets in which each ball of a different color represents atoms of a different element.
A basic concept of the atomic theory is that the chemical and physical properties
of a substance are determined by the distribution of outermost shell electrons in its
atoms and by the spatial arrangement of these atoms in the structure of the substance.
Lewis Dot formulas are two dimensional representations that use the arrangement of
outer shell electrons to give basic information on the three dimensional arrangement of
atoms in molecules and polyatomic ions.
Experimental techniques such as x-ray or neutron diffraction in crystals, infrared,
Raman and microwave spectroscopy, and dipole measurements provide information on
the relative positions or geometric arrangement of atoms in real molecules and in
polyatomic ions. Experimental data on shapes and polarity agree very closely with
shapes and polarity predicted from models for simple molecules and polyatomic ions.
The following rules and procedures are given as a guide in drawing Lewis
Electron Dot Formulas.
Drawing Lewis Structures
Rule 1. For small molecules and polyatomic ions, place the element with the lowest
electronegativity in the center and arrange the more electronegative atoms around it.
Note:- Hydrogen should not be used as a central atom.
2
Oxygen atoms do not bond to each other except in O2 (dioxygen), O3 (ozone),
O22- (peroxide ion), and O2- (superperoxide ion).
Rule 2. In oxyacids such as HNO3 and H2SO4, hydrogen atoms are usually bonded to
oxygen atoms which in turn are bonded to the central atom.
Arrangement of Electron Dots:-
Count the total number of valence electrons from all atoms in the formula,
including electrons due to negative charge, if any.
Arrange atoms around the central atom; remember to apply Rule 2.
Two electrons are used to form a bond.
Complete the octets of the atoms attached to the central atom; remember that
hydrogen can accommodate only 2 electrons.
Put any remaining electrons on the central atom to satisfy its octet. These extra
electrons are shown as pairs.
If the central atom has less than an octet, form double or triple bonds with the
surrounding atoms.
There are compounds which are exceptions to the octet rule. For instance, in
BF3 the central atom has less than 8 electrons. Such species are called electron-
deficient molecules. On the other hand, the central atoms in PCl5, SF6, IF5, etc.
Elements in the third row of the periodic table and beyond often exhibit expanded octets
of up to 12 electrons.
Electron-Domain Geometry (Electronic Geometry)
The VSEPR Theory states that shared (bonding) and unshared (nonbonding) electron
pair domains around the central atom arrange themselves as far apart as possible. In
other words, electron domains will orient themselves so as to minimize the repulsion
between them. Electron pairs used to form multiple bonds (i.e. double or triple bonds)
are counted as one electron domain. Electron pairs used to form single bonds are
counted as electron domains.
Example. What is the number of electron domains around the central atom in CO32-?
3
O
C
O
O
2-
The three electron domains in CO32- arrange themselves so as to minimize repulsion
with each other. In other words, the electron domains occupy three regions around the
carbon atom forming a trigonal planar geometry.
Molecular Geometry (Molecular Shape)
Molecular geometry refers to the relative positions of the atoms around a central atom of
a molecule or polyatomic ion. Molecular geometry of a molecule is determined by how
the surrounding atoms are arranged around the central atom, which is in turn determined
by how the electron domains are arranged around the central atom. The following link
can be used to determine the electronic and molecular geometries of simple molecules:
https://billvining.com/mmlib_sims/#gen_8_2.
Molecular Polarity (Dipole Moment)
In polyatomic molecules/ions, the presence of polar bonds may or may not result in a
polar molecule, depending on the molecular geometry. If the molecular geometry of a
molecule/polyatomic ion is completely symmetrical, the molecule/polyatomic ion is
nonpolar. In other words, in a totally symmetric molecule individual bond dipoles cancel
each other completely (i.e. the net dipole moment is zero). If the molecular geometry is
not totally symmetric, the molecule has a net dipole moment and hence is polar. Polarity
influences both physical and chemical properties of molecules. A molecule is nonpolar
regardless of its geometry, if it does not contain polar bonds. An individual bond is polar
if the two bonding atoms have sufficiently different electronegativities.
_
There are three electron domains around C atom:
i.e. two single bonds, counted as two electron domains
and one double bond counted as one electron domain.
4
Name: _______________________ Date: _______________
CHM 114
PROCEDURE
i) Watch the lab recording posted on Canvas along with the lab handout.
Predict the molecular geometry and polarity of the molecules/ions listed in
Table 3.
ii) Draw the Lewis structures of the molecules/ions in the space provided in the
table and state the molecular geometry (shape).
iii) Check if the geometries you predicted are correct using the following
simulation: https://billvining.com/mmlib_sims/#gen_8_2.
iv) Predict the polarity of the molecules/ions based on their geometries.
Table 1. Lewis structure, molecular geometry and polarity of selected molecules
and ions.
Molecule
/Ion
Lewis Structure
Name of
Molecular
Geometry
Polar or
Nonpolar?
XeF4
PCl3
Molecular geometry and polarity
5
Table 1 continued ………..
IF4-
OF2
SF4
SeF6