Electrochemistry has been undergoing significant transformations in the last few decades. It is now the province of academics interested only in measuring thermodynamic properties of solutions and of industrialists using electrolysis or manufacturing batteries, with a huge gap between them. It has become clear that these, apparently distinct subjects, alongside others, have a common ground and that they have grown towards each other, particularly as a result of research into the rates of electrochemical processes. Such evolution is due to a number of factors, and offers the possibility of carrying out reproducible, dynamic experiments under an ever-increasing variety of conditions with reliable and sensitive instrumentation. This has enabled many studies of a fundamental and applied nature, to be carried out.

" This is an advanced course on modeling, design, integration and best practices for use of machine elements such as bearings, springs, gears, cams and mechanisms. Modeling and analysis of these elements is based upon extensive application of physics, mathematics and core mechanical engineering principles (solid mechanics, fluid mechanics, manufacturing, estimation, computer simulation, etc.). These principles are reinforced via (1) hands-on laboratory experiences wherein students conduct experiments and disassemble machines and (2) a substantial design project wherein students model, design, fabricate and characterize a mechanical system that is relevant to a real world application. Students master the materials via problems sets that are directly related to, and coordinated with, the deliverables of their project. Student assessment is based upon mastery of the course materials and the student's ability to synthesize, model and fabricate a mechanical device subject to engineering constraints (e.g. cost and time/schedule)."

This semester-long project on conducting an environmental audit of a college campus can be done by an individual or by groups of students working in teams. Each group will research a different aspect of campus operations; they will collect data, analyze their findings, and make recommendations for improvements. This SERC Starting Point site includes learning goals, context for use, teaching tips and materials, assessment, and references.

The activity described herein can be implemented in introductory chemistry and high school chemistry courses. The main goal of the project is to integrate a ubiquitous biodiesel production with experiential learning by providing a community-based project. The students work in groups, research the benefits of using biodiesel over petroleum-based diesel, collect waste cooking oil from home or restaurants, develop simple and cost-effective methods to produce biodiesel.

The activity described herein can be implemented in introductory chemistry and high school chemistry courses. The main goal of the project is to integrate a ubiquitous biodiesel production with experiential learning by providing a community-based project. The students work in groups, research the benefits of using biodiesel over petroleum-based diesel, collect waste cooking oil from home or restaurants, develop simple and cost-effective methods to produce biodiesel, as well as making soap.

This is the first semester in a two-semester introductory course focused on current theories of structure and mechanism in organic chemistry, their historical development, and their basis in experimental observation. The course is open to freshmen with excellent preparation in chemistry and physics, and it aims to develop both taste for original science and intellectual skills necessary for creative research.

This is a continuation of Freshman Organic Chemistry I (CHEM 125a), the introductory course on current theories of structure and mechanism in organic chemistry for students with excellent preparation in chemistry and physics. This semester treats simple and complex reaction mechanisms, spectroscopy, organic synthesis, and some molecules of nature.

This ebook contains background information, video tutorials and virtual exercises for the Biochemistry Laboratory module. Gas chromatography (GC) and mass spectrometry (MS) are analysis methods that require a lot of background information and intense theory. This interactive ebook will help you understand the information behind these analysis methods, and is accessible through iTunes.

An integrated course stressing the principles of biology. Life processes are examined primarily at the molecular and cellular levels. Intended for students majoring in biology or for non-majors who wish to take advanced biology courses.

The modern human experience places a large emphasis upon the material world. From the day of our birth to the day we die, we are frequently preoccupied with the world around us. Whether struggling to feed ourselves, occupying ourselves with modern inventions, interacting with other people or animals, or simply meditating on the air we breathe, our attention is focused on different aspects of the material world. In fact only a handful of disciplines—certain subsets of religion, philosophy, and abstract math—can be considered completely unrelated to the material world. Everything else is somehow related to chemistry, the scientific discipline which studies the properties, composition, and transformation of matter.

Chemistry is a challenging and often abstract science, but as you progress through this course we
hope you will discover that chemistry is also exciting and that many of the key concepts in chemistry
are both important and relevant to life on earth. Throughout this semester we will provide you with
the basic skills and knowledge to think and feel like a chemist. You will learn that chemistry is
exciting!

This survey chemistry course is designed to introduce students to the world of chemistry. In this course, we will study chemistry from the ground up, learning the basics of the atom and its behavior. We will apply this knowledge to understand the chemical properties of matter and the changes and reactions that take place in all types of matter. Upon successful completion of this course, students will be able to: Define the general term 'chemistry.' Distinguish between the physical and chemical properties of matter. Distinguish between mixtures and pure substances. Describe the arrangement of the periodic table. Perform mathematical operations involving significant figures. Convert measurements into scientific notation. Explain the law of conservation of mass, the law of definite composition, and the law of multiple proportions. Summarize the essential points of Dalton's atomic theory. Define the term 'atom.' Describe electron configurations. Draw Lewis structures for molecules. Name ionic and covalent compounds using the rules for nomenclature of inorganic compounds. Explain the relationship between enthalpy change and a reaction's tendency to occur. (Chemistry 101; See also: Biology 105. Mechanical Engineering 004)

An in-depth introduction to chemical equilibrium, aqueous solution chemistry, thermodynamics, electrochemistry, and kinetics. This course focuses on developing the fundamental principles of thermodynamics and chemical equilibria and the applications of these principles to aqueous solution chemistry.

Chemistry is a challenging and often abstract science, but as you progress through this course we hope you will discover that chemistry is also exciting and that many of the key concepts in chemistry are both important and relevant to life on earth. Throughout this semester we will provide you with the basic skills and knowledge to think and feel like a chemist. You will learn that chemistry is exciting!

This course was created as part of the Open Pedagogy Fellowship, through the Mina Rees Library at The Graduate Center, CUNY.

Read more about the process of course design here: https://gclibrary.commons.gc.cuny.edu/2021/04/29/oer-in-science-catching-up-in-stem/

The overall goal of the authors with General Chemistry: Principles, Patterns, and Applications was to produce a text that introduces the students to the relevance and excitement of chemistry.Although much of first-year chemistry is taught as a service course, Bruce and Patricia feel there is no reason that the intrinsic excitement and potential of chemistry cannot be the focal point of the text and the course. So, they emphasize the positive aspects of chemistry and its relationship to studentsŐ lives, which requires bringing in applications early and often. In addition, the authors feel that many first year chemistry students have an enthusiasm for biologically and medically relevant topics, so they use an integrated approach in their text that includes explicit discussions of biological and environmental applications of chemistry.

Fundamental principles of biochemistry. Analysis of the mode of action and structure of regulatory, binding, and catalytic proteins. The tools and analytical methods that biochemists use to dissect biological problems. Analysis of the mode of action and structure of regulatory, binding, and catalytic proteins.

The Foundations of Chemistry SCC 110 course is required for LaGuardia's Health Sciences students interested in the Nursing, Dietetic Technician and Veterinary Technician programs. This course has been designated for the Inquiry and Problem Solving competency as well the Digital Communication ability. SCC 110 students will use SCC 110 lecture material and information in the SCC 110 lab manual to perform an electrophilic addition. Students will be able to correlate the organic theory concepts with the experiment by making physical observations (e.g., color changes) when carrying out the lab procedures. The student findings will be synthesized and expressed by making an in-class video and drawing the reaction using chemistry software.
Students, who successfully complete the hydrocarbon reaction lab and produce a corresponding satisfactory digital media report, will ideally have engaged in the assignment for at least three hours in lab followed by an additional 2-3 hours completing the digital components of the lab. The assignment is worth 2.5% of the final grade and is at the midpoint in the core competency for health sciences. This lab assignment was developed in the CTL seminar- Pedagogy of the Digital Ability where assignments were devised in the seminar followed by revisions of the assignment in a charrette format.
LaGuardia's Core Competencies and Communication Abilities
The assignment will enable students to use digital media to explain complex chemistry concepts while improving digital literacy. In more detail, this is shown where SCC 110 students are asked to submit/upload a video of themselves performing an organic chemical reaction and providing audio commentary on the experimental observations with an explanation of the underlying chemistry principles. The second part of the assignment will entail students using chemistry software to draw out the chemical reaction from the lab and uploading the two digital media products in their ePortfolio. The crafted digital report addresses all four dimensions of the digital communication rubric with an emphasis on multimodal communication. It describes both on a macroscopic and microscopic level the step by step organic reaction of an alkene plus bromine to create a haloalkane. Students will be able to use appropriate scientific language to explain the reaction mechanism to the undergraduate scientific student community. The design of the experiment incorporates one of SCC 110's course objective, which is to introduce students to concepts about chemical bonding.

General Chemistry is a two-semester course (General Chemistry I, SCC 201 and General Chemistry II, SCC 202) required for majors in Biology and Environmental Sciences.
This lab experiment, aligned to LaGuardia Community College‰Ûªs Inquiry and Problem Solving Core Competency and Written Communication Ability was designed for General Chemistry I (SCC 201 Honors) course. Honors courses in LaGuardia emphasize critical thinking, analytical writing, and introduce students to research. This lab experiment provides an opportunity for students to engage in hands-on laboratory work, to develop laboratory skills, and to conduct research in the classroom by using two water soluble porphyrins to detect transition metal ions in a solution and on a paper support. Overall, this experiment was designed to meet the demand for undergraduate research experiences and to engage all the students in addressing a research question or problem that is of interest to the scientific community.
In order to demonstrate their learning, students write a formal lab report which includes an understanding of experiment procedures (methods and techniques), safety hazards, instrumentation, understanding of concepts and theories gained by performing the experiment, collecting data through observation and/or experimentation, interpretation of the data (Ultraviolet-visible spectra), analysis of the data in tables and graphs, and drawing conclusions and perspective from the experiment. The knowledge students gain during this lab experiment will be useful to connect with future chemistry courses and can also be utilized to do research. The lab write-up is deposited for the assessment of the Written Communication Ability to which SCC 201 is aligned.
This experiment also raises awareness about a global concern. Students detect transition metal ions in aqueous solutions by use of porphyrins. Due to rapid growth in technology and industrialization, transition metals are used in large amounts in a variety of electronic products. The improper preservation of the industrial wastes leads to accumulation of these metals into water resources, which can create danger to human health and the environment. Therefore, there is a need to carefully monitor and frequently detect transition metal ions content in the environment.
This lab experiment was implemented in an Honors section of General Chemistry SCC 201 and was worth about 3.5% of the final grade. The students are likely to spend 3 hours completing the experiment in the lab and another 3-4 hours completing the lab write-up.
The Program Goals that this assignment targets:
1. To provide training to the students in various lab techniques and how to utilize these techniques to conduct research.
The Student Learning Objective (s) that this assignment targets:
1. Students will have an enhanced conceptual understanding of the theory to practice relationship and will achieve higher level reasoning skills.
2. Students will be able to develop their practical competence in laboratory work.
3. Students will be able to collect data through observation and/or experimentation, preparation of solutions of known concentration, characterize the compounds by UV-vis spectra, and draw conclusions and perspective of the experiment.
4. Communicate their results through the formal lab report format of: Introduction, Chemicals, Procedure, Data, Discussion and References.
LaGuardia‰Ûªs Core Competencies and Communication Abilities
The Course Objective (s) that this assignment targets:
1. Based on the principles of environmental chemistry, students will be able to detect the transition metal ions using a porphyrin as a sensor and explore the complex connections between chemistry and real world issues.
2. Observe, collect, analyze and interpret experimental data and graph the UV visible spectra using Microsoft Excel.