Skip to main content

NanoEngineering (NANO)

[ undergraduate program | courses | faculty ]

BUSINESS AFFAIRS:
240A Structural Materials Engineering Building, Warren College
STUDENT AFFAIRS:
241 Structural Materials Engineering Building, Warren College

http://nanoengineering.ucsd.edu

All courses, faculty listings, and curricular and degree requirements described herein are subject to change or deletion without notice.

Graduate Program

Degree and Program Options

The NanoEngineering Program offers graduate instruction leading to the MS and PhD in NanoEngineering and the PhD in NanoEngineering with a Specialization in Multi-scale Biology.

The Chemical Engineering Program offers graduate instruction leading to the MS and PhD in Chemical Engineering and the PhD in Chemical Engineering with a Specialization in Multi-scale Biology.

NanoEngineering Program (NANO)

Program Objectives

The Department of NanoEngineering (NE) now offers the MS and PhD in NanoEngineering with a new, unique curriculum centered on our strong research position in nano-biomedical engineering and nanomaterials synthesis and characterization activities. The NanoEngineering Graduate Program provides a course of study for both the MS and PhD, with a focus on underlying scientific, technical, and engineering challenges for advancing nanotechnology in the controlled synthesis of nanostructured materials, especially for biomedical, energy, and environmentally related technologies. Our graduate degree program is uniquely designed to educate students with a highly interdisciplinary curriculum, focusing on core scientific fundamentals, but extending the application of that fundamental understanding to complex problems requiring the ability to integrate across traditional science and engineering boundaries. Specific courses in our core cluster address both the fundamental science and the integration of this science into engineering problem solving. Three main educational paths within the single degree title ‘NanoEngineering’ are proposed:

  • Biomedical Nanotechnology
  • Molecular and Nanomaterials
  • Nanotechnologies for Energy and the Environment

The new NanoEngineering curriculum has the following objectives:

  • Prepare students for nanotechnology by providing them with a sound grounding in multidisciplinary areas of nanoscience and nanoengineering.
  • Increase students’ understanding of materials and their properties at the atomic and nanometer level, including an understanding of the intimate relationship between material scale (nanostructure) and the properties/functionality of materials.
  • Prepare graduates who, while skilled in areas of nanoscience and nanoengineering, will be qualified for jobs in traditional science-based industries and government laboratories and, as the nanotechnologies emerge and mature, will be positioned for jobs in these applied areas. This program will be anticipating trends and providing students with integrated, cross-disciplinary scientific knowledge and professional skills.
  • Educate a new generation of engineers who can participate in, and indeed seed, new high-technology companies that will be the key to maintaining jobs, wealth and educational infrastructures as nanotechnology results in a new industrial revolution.
  • Enable the students to develop a range of professional, scientific, and computational skills that will enhance employment opportunities in a wide range of industrial and governmental institutions.
  • Prepare students for the workplace through developing their ability to contribute constructively to multidisciplinary teams, learn team engineering principles and methods, to communicate both orally and in written form, and to be familiar with modern, computer-based communication technology. This will be achieved using nontraditional education techniques including group-based problem-based learning, flexible delivery and web-based interactive tutorials.

In NanoEngineering, we design and manufacture devices and systems that exploit the unique properties of nanoscale materials to create entirely new functionality and capabilities. Due to the scale of engineering involved, the field of NanoEngineering is inherently interdisciplinary that often utilizes biochemical processes to create nanoscale materials designed to interact with synthetic inorganic materials. The curriculum is built to address the educational needs of this new engineering field.

NanoEngineering BS/MS Contiguous Program

A contiguous terminal program leading to a bachelor of science and master of science degree in NanoEngineering is offered to a student with junior standing who has an overall UC San Diego GPA of 3.0 and a 3.0 GPA in upper-division STEM courses in the major. Students must apply for admission to the program during the last quarter of their junior year (more specifically, the fourth quarter prior to the receipt of the BS). Details of the program are available from the Department of NanoEngineering Graduate Student Affairs Office.

The MS program is intended to extend and broaden an undergraduate background and/or equip practicing engineers with fundamental knowledge in their particular fields. The degree is offered under both the Plan I, Thesis Plan, or Plan II, Comprehensive Examination Plan.

Graduate Program

The NanoEngineering Program offers graduate instruction leading to the MS and PhD in NanoEngineering.

Admission is in accordance with the general requirements of the Graduate Division, which requires at least a BS in some branch of engineering, sciences, or mathematics; an overall GPA of 3.0, and three letters of recommendation from individuals who can attest to the academic or professional competence and to the depth of their interest in pursuing graduate study. Students who have already received a prior MS in a similar field will not be admitted to the program.

In addition, all applicants are required to submit GRE General Test Scores. The university-wide minimum TOEFL score required for consideration for graduate admission is 64 for the paper-delivered test, and 85 for the internet-based test (iBT). The university-wide minimum IELTS Academic Training exam score required for consideration for graduate admission is band score 7. The minimum PTE Academic score required for graduate admission is overall score 65. Applicants with marginal scores on the exam may be required to pass an English proficiency test upon arrival at UC San Diego or to enroll in an English course until the required proficiency is attained.

Applicants are judged competitively. Based on the candidate’s background, qualifications, and goals, admission to the program is in one of three categories: MS only, MS, or PhD. Admission to the MS only category is reserved for students for whom the MS is likely to be the terminal graduate degree. The MS designation is reserved for students currently interested in obtaining an MS but who at a later time may wish to continue in the doctoral degree program. Admission to the PhD program is reserved for qualified students whose final aim is a doctoral degree.

Nonmatriculated students are welcome to seek enrollment in graduate-level courses via UC San Diego Extended Studies concurrent registration program, but an Extended Studies student’s enrollment in a graduate course must be approved by the instructor.

Master’s Degree Program

The program offers the MS in NanoEngineering under both the Thesis (Plan I) and the Comprehensive Examination (Plan II); see “Graduate Admission: Master’s Degrees.” The requirements for the MS degree are as follows:

  1. All students must complete a total of thirty-six units.
  2. All students must complete five mandatory core courses (NANO 201, 202, 203, 205, 206), and twelve units of elective courses, including one elective course from any focus area selected from an approved list of graduate courses with the consent of a faculty adviser. In addition, enrollment in NANO 200 each quarter is required. See “Courses” for descriptions.
  3. Students either complete a thesis (Plan I) or pass a comprehensive examination (Plan II) as described in the “Graduate Admission: Programs of Study” section of this catalog.
  4. Students must meet all other requirements established by the university.

The three focus areas and related courses are

Focus 1 – Biomedical Nanotechnology: NANO 210, 241, 242, 243, 244, 247A, 247B, 247C, 262, 272, 273

Focus 2 – Molecular and Nanomaterials: NANO 204, 227, 230, 234, 238, 239, 241, 242, 250, 251A, 251B, 252, 253, 255, 263, 264, 265, 267, 268, 271, 275, 280, 281

Focus 3 – Nanotechnologies for Energy and the Environment: NANO 212, 241, 245, 255, 257, 258, 259, 260, 261, 266, 267, 269, 279

Students who transfer with some graduate credit or an MS from another institution will have their records reviewed by a faculty adviser, and must meet the department requirements for transfer credits in order to be considered for an appropriate individual course of study. The MS program is intended to extend and broaden an undergraduate education with fundamental knowledge in different fields. The degree may be terminal, or obtained on the way to the PhD. The degree is offered under both the Thesis Plan I and the Comprehensive Examination Plan II.

MS Time Limit Policy: Full-time MS students are permitted seven quarters in which to complete all requirements. While there is no written time limit for part-time students, the department has the right to intervene and set individual deadlines if it becomes necessary.

Course requirements: All MS students must complete a total of thirty-six units, which include a core of five courses (twenty units), with letter grades of C– or better.

No more than a total of eight units of NANO 296 and 298 may be applied toward the course work requirement. Units in seminars (NANO 200 and 279) may not be applied toward the degree requirement.

Thesis Plan I: Completion of the research thesis (NANO 299) fulfills twelve units toward the total graduation requirement. The balance is made up of the five core courses (twenty units) and one additional elective course (four units) subject to the restrictions described above.

Comprehensive Examination Plan II: This plan involves course work only and culminates in a comprehensive examination based on topics selected from the core courses. In addition to the five core courses (twenty units), one must choose an additional four electives (sixteen units) subject to the restrictions of NANO 279, 296, and 298 described above. A student should consult their academic adviser to choose an appropriate course schedule.

A sample program is shown:

Fall

Winter

Spring

NANO 201

NANO 203

NE Elective

NANO 202

NANO 205

NE Elective

NE Elective

NANO 206

NE Elective

NANO 200

NANO 200

 NANO 200

Change of Degree: Upon completion of the requirements for the MS, students admitted as MS only or MS candidates are not automatically eligible for admission to the PhD program. MS students who are considering pursuing a doctorate should contact the graduate coordinator to discuss the requirements, and must also pass the qualifying examination (or MS comprehensive exam) by a 70 percent or higher grade.

Doctoral Degree Program

The PhD program is intended to prepare students for a variety of careers in research and teaching. The emphasis is on research. All students, in consultation with their advisers, develop appropriate course programs that will prepare them for the Preliminary Qualifying Examination and for their dissertation research. These programs must be planned to meet the time limits established to advance to candidacy and to complete the requirements of the degree. A PhD in NanoEngineering requires the selection of a specific focus (Biomedical Nanotechnology, Molecular and Nanomaterials, or Nanotechnologies for Energy and the Environment), and consists of the successful completion of ten courses: the five required core courses, three department approved electives from the student’s selected focus, and two electives from any of the two remaining focuses. While only one degree title is offered—NanoEngineering—the choice of a specific focus area is to ensure that the graduate student curriculum is both tailored to their interest and sufficiently in-depth to ensure a complete understanding of their field of interest.

After completing the MS degree (or meeting equivalent requirements) and meeting the minimum standard on the comprehensive examination to be admitted to or continue in the PhD program, a student must:

  1. Meet all the university’s residency and other requirements.
  2. Successfully complete three advanced graduate courses (beyond those required for the MS), which have been approved by the student’s dissertation adviser.
  3. Enroll in NANO 200 each quarter. See “Courses” for descriptions.
  4. Pass the Literature Review Examination. This requirement must be successfully completed within one year after passing the Comprehensive Examination.
  5. Pass the PhD Qualifying Examination (Senate Exam) to be advanced to PhD candidacy.
  6. Successfully complete and defend a dissertation, which in the opinion of the dissertation committee contains original work that should lead to publication of at least one significant article in an appropriate refereed journal.

In principle, it should be possible to finish the MS degree in three quarters, and a PhD in an additional three years. PhD time limits are as follows: precandidacy—four years; support limit—six years; total time limit—seven years. (See “Graduate Division–PhD Time Limits” for further explanation.)

Departmental Examinations
All PhD students are required to pass four examinations. The first is a written Comprehensive Examination, which should be taken within three quarters of full-time graduate study. The second is a Literature Review Examination (detailed below). The third is the PhD Senate Exam (often referred to as “Advancement to Candidacy Exam”). The last is the dissertation defense.

The Comprehensive Examination
The examination will consist of questions from each of the five core courses. A passing grade is 60 percent for successful completion of the master’s degree, and 70 percent for qualification to the PhD program. The examination will not exceed six hours in duration. Typically, students take the exam after one year of full-time enrollment. This exam may only be retaken once before the end of the second year of study.

The Literature Review Examination
The Literature Review Examination tests the student’s ability to prepare and present a comprehensive overview of a topic based on existing journal literature. It should be a comprehensive discussion of the literature, scientific theory, problems or theoretical deficiencies, and possible areas of research in some area related to nanoscience or nanoengineering. The topic may be in the general area in which the student plans to pursue his or her thesis research, or it may be in an unrelated field of nanoengineering. The topic must be approved by the three faculty member committee in advance of the seminar. The Literature Review Examination will conclude with a short preliminary overview of the students’ research project or their research proposal. This exam must occur within one year of the student having passed the Comprehensive Examination.

The PhD Senate Exam: Upon completion of formal course requirements, each student will be required to take a written and oral qualifying examination that will advance the student to candidacy in the PhD program. It is often known as the “Senate Exam” or “Advancement to Candidacy” exam. Prior to this examination, each student, in consultation with his or her faculty adviser, will establish a dissertation committee of four faculty members. The committee will include the student’s PhD adviser as the chair of the committee. The committee will consist of two faculty members who are affiliated with the Department of NanoEngineering. At least one member must be from a primary appointment (department) different from the committee chair; at least one member must be tenured or emeritus. The doctoral committee chair (faculty adviser) will have the major responsibility for the student’s research and dissertation.

At UC San Diego, the university “Candidacy/Senate” Examination is a requirement for a graduate student to complete satisfactorily, once a thesis project has been decided upon. It is strongly recommended, except in special circumstances, that the student complete this examination prior to the end of the first four years in the program. The format for this examination is consistent with the highest standards held by UC San Diego. The student should write a detailed candidacy report in the format of an NIH, NSF, or similar grant proposal. The project and the report should be interdisciplinary and should have input from the thesis adviser. Any publications or supplementary material may be attached. It is expected that the student will meet at least annually with the committee to update the members on his or her progress.

Dissertation Defense: This is the final PhD examination. Upon completion of the dissertation research project, the candidate writes a dissertation that must be successfully defended in an oral examination and public presentation conducted by the doctoral committee. A complete copy of the student’s dissertation must be submitted to each member of the doctoral committee two weeks before the defense. It is understood that this copy of the dissertation given to committee members will not be the final copy, and that the committee members may request changes in the text at the time of the defense. This examination may not be conducted earlier than three quarters after the date of advancement to doctoral candidacy. Acceptance of the dissertation by the Graduate Division and the university librarian represents the final step in completion of all requirements for the PhD.

Teaching Experience: Prior to the dissertation defense, the candidate must serve at least one quarter as a teaching assistant, with the responsibility to hold a problem-solving section one hour a week.

Annual Evaluation: In the spring of each year, the faculty adviser evaluates each doctoral student’s overall performance in course work, research, and prospects for financial support for future years. A written assessment is given to the student after the evaluation. If a student’s work is found to be inadequate, the faculty may determine that the student cannot continue in the graduate program.

PhD in NanoEngineering with Specialization in Multi-scale Biology
A PhD specialization in multi-scale biology, spanning four schools—Jacobs School of Engineering, Health Sciences, Biological Sciences, and Physical Sciences, is available to doctoral candidates in NanoEngineering. The PhD specialization is designed to allow students to obtain standard basic training in their chosen field, along with training in integrative and quantitative analysis across multiple scales of biological organization from molecule to organism to health and disease. It educates a new cadre of PhD scientists to undertake interdisciplinary work at the interfaces between the biological, medical, physical, and engineering sciences.

Chemical Engineering Program (CENG)

Program Objectives

The Chemical Engineering Program has affiliated faculty from the Department of NanoEngineering, Department of Mechanical and Aerospace Engineering, Department of Chemistry and Biochemistry, and the Department of Bioengineering. The curricula at both the undergraduate and graduate levels are designed to support and foster chemical engineering as a profession that interfaces engineering and all aspects of basic sciences (physics, chemistry, and biology).

The primary educational objectives of the Chemical Engineering Program are

  • To provide chemical engineering students with a strong technical education and communication skills that will enable them to have successful careers in a wide range of industrial and professional environments.
  • To prepare chemical engineering students for rapidly changing technological environments with the core knowledge central to multidisciplinary development and personal improvement throughout their professional careers.
  • To instill in chemical engineering students a strong sense of humanistic values and professionalism such that they can conduct ethically and knowledgeably regarding technological impact in societal issues.

The curriculum is designed to prepare chemical engineering graduates for further education and personal development through their entire professional career. We strive to accomplish these goals by providing a rigorous and demanding curriculum that incorporates lectures, discussions, laboratory and project development experiences in basic sciences, mathematics, engineering sciences, and design as well as the humanities and social sciences.

Chemical Engineering BS/MS Contiguous Program

A contiguous, terminal program leading to a bachelor of science and a master of science degree in chemical engineering is offered to a student with junior standing who has an overall UC San Diego GPA of 3.0 and a GPA of 3.0 in upper-division STEM courses in the major. Students must apply for admission to the program during the last quarter of their junior year (more specifically, the fourth quarter prior to the receipt of the BS). Details of the program are available from the Department of NanoEngineering Graduate Affairs Office.

The MS program is intended to extend and broaden an undergraduate background and/or equip practicing engineers with fundamental knowledge in their particular fields. The degree is offered under both the Thesis Plan I and the Comprehensive Examination Plan II.

Graduate Program

The Chemical Engineering Program offers graduate instruction leading to the MS and PhD in chemical engineering. The nanotechnology concentration signifies that four elective courses are chosen from the approved courses in this area.

Admission is in accordance with the general requirements of the graduate division, which requires at least a BS in some branch of engineering, sciences, or mathematics; an overall GPA of 3.0, and three letters of recommendation from individuals who can attest to the academic or professional competence and to the depth of their interest in pursuing graduate study. Students who have already received a prior MS in a similar field will not be admitted to the program.

In addition, all applicants are required to submit GRE General Test Scores. The university-wide minimum TOEFL score required for consideration for graduate admission is 64 for the paper-delivered test, and 85 for the internet-based test (iBT). The university-wide minimum IELTS Academic Training exam score required for consideration for graduate admission is band score 7. The minimum PTE Academic score required for graduate admission is overall score 65. Applicants with marginal scores on the exam may be required to pass an English proficiency test upon arrival at UC San Diego or to enroll in an English course until the required proficiency is attained.

Applicants are judged competitively. Based on the candidate’s background, qualifications, and goals, admission to the program is in one of three categories: MS-only, MS, or PhD. Admission to the MS-only category is reserved for students for whom the MS is likely to be the terminal graduate degree. The MS designation is reserved for students currently interested in obtaining an MS but who at a later time may wish to continue in the doctoral degree program. Admission to the PhD program is reserved for qualified students whose final aim is a doctoral degree.

Both NanoEngineering and chemical engineering nonmatriculated students are welcome to seek enrollment in graduate-level courses via UC San Diego Extended Studies concurrent registration program, but an Extended Studies student’s enrollment in a graduate course must be approved by the instructor.

Master’s Degree Program

The MS program is intended to extend and broaden an undergraduate education with fundamental knowledge in different fields. The degree may be terminal, or obtained on the way to the PhD. The degree is offered under both the Thesis Plan I and the Comprehensive Examination Plan II.

MS Time Limit Policy: Full-time MS students are permitted seven quarters in which to complete all requirements. While there is no written time limit for part-time students, the department has the right to intervene and set individual deadlines if it becomes necessary.

Course requirements: All MS students must complete a total of thirty-six units, which includes a core of five courses (twenty units): CENG 210A, CENG 221A-B, CENG 251, and CENG 252, with letter grades of C– or better. To maintain a certain balance in the core, no more than two mathematics courses should be chosen among the choices of applied mathematics (MAE 294AB or MATH 210AB) and numerical mathematics (MAE 290AB or MATH 270AB).

No more than three courses (twelve units) of upper-division courses may be applied toward the total course work requirement. No more than a total of eight units of CENG 296 and 298 may be applied toward the course work requirement. Units in seminars (CENG 259, CENG 205) may not be applied toward the degree requirement.

Thesis Plan I: Completion of the research thesis (CENG 299) fulfills twelve units toward the total graduation requirement. The balance is made up of the five core courses (twenty units) and one elective course (four units) subject to the restrictions described above.

Comprehensive Examination Plan II: This plan involves course work only and culminates in a comprehensive examination based on topics selected from the core courses. In addition to the five core courses (twenty units), one must choose an additional four electives (sixteen units) subject to the restrictions of CENG 259, 296, and 298 described above. A student should consult with the graduate coordinator to choose an appropriate course schedule, including alternatives in bioengineering, electrical and computer engineering, materials science, basic sciences, and mathematics. The nanotechnology concentration signifies that four elective courses are chosen from the approved courses in this area.

A sample program is shown:

Fall

Winter

Spring

Core selections

CENG 210A

CENG 221B

 

CENG 221A

CENG 251

 

 

CENG 252

 

Seminar

CENG 205

CENG 205

CENG 205

Nanotechnology concentration

CENG 211

CENG 213

 

CENG 212

CENG 214

CENG 215

Change of Degree: Upon completion of the requirements for the MS degree, students admitted as MS-only or MS candidates are not automatically eligible for admission to the PhD program.

MS students who are considering pursuing a doctorate should contact the graduate coordinator to discuss the requirements, and must also pass the qualifying examination (or MS comprehensive exam) by a 70 percent or higher grade.

Doctoral Degree Program

The PhD program is intended to prepare students for a variety of careers in research and teaching. The emphasis is on research. After completing the MS degree requirements, all students, in consultation with their faculty advisers, develop appropriate course programs that will prepare them for the Preliminary Qualifying Examination and for their dissertation research. These programs must be planned to meet the time limits established to advance to candidacy and to complete the department and university requirements of the degree.

PhD Time Limit Policy: Precandidacy status is limited to four years. Doctoral students are eligible for university support for six years. The defense and submission of the doctoral dissertation must be within seven years.

Departmental Examinations

All PhD students are required to pass four examinations. The first is a Preliminary Qualifying Examination, which should be taken within three quarters of full-time graduate study and passed with at least a 70 percent grade in all components of the exam. The second is a literature review examination (detailed below), which should be completed by the end of the second year. The third is the PhD Senate Examination (often referred to as Advancement to Candidacy Exam). The last is the Dissertation Defense.

Preliminary Qualifying Examination: The examination is intended to determine a candidate’s basic understanding of engineering fundamentals and the candidate’s ability to pursue successfully a research project at a level appropriate for the doctorate. The examination will consist of questions from each of the five core courses. A passing grade is 60 percent for successful completion of the master’s degree and 70 percent for qualification to the doctoral program. The examination will not exceed six hours in duration. Typically, students take the exam after completion of the core courses. This exam may only be retaken once before the end of the second year of study.

Literature Review Examination: The Literature Review Examination tests the student’s ability to prepare and present a comprehensive overview of a topic based on existing journal literature. It should be a comprehensive discussion of the literature, scientific theory, problems or theoretical deficiencies, and possible areas of research in some area related to nanoscience or NanoEngineering. The topic may be in the general area in which the student plans to pursue his or her thesis research, or it may be in an unrelated field of NanoEngineering. The topic must be approved by the three faculty member committee in advance of the seminar. The Literature Review Examination will conclude with a short preliminary overview of the students’ research project or their research proposal. This exam must occur within one year of the student having passed the Comprehensive Examination.

PhD Senate Examination: Upon completion of formal course requirements, each student will be required to take a written and oral qualifying examination that will advance the student to candidacy in the doctoral program. It is often known as the Senate Exam or Advancement to Candidacy Exam. Prior to this examination, each student, in consultation with his or her faculty adviser, will establish a dissertation committee of four faculty members.

The committee will include the student’s doctoral adviser as the chair of the committee. The committee will consist of two faculty members who are affiliated with the Department of NanoEngineering. At least one member must be from a primary appointment (department) different from the committee chair; at least one member must be tenured or emeritus. The doctoral committee chair (faculty adviser) will have the major responsibility for the student’s research and dissertation.

At UC San Diego, the university Candidacy/Senate Examination is a requirement for a graduate student to complete satisfactorily, once a thesis project has been decided upon. It is strongly recommended, except in special circumstances, that the student complete this examination prior to the end of the first four years in the program. The format for this examination is consistent with the highest standards held by UC San Diego. The student should write a detailed candidacy report in the format of an NIH, NSF, or similar grant proposal. The project and the report should be interdisciplinary and should have input from the thesis adviser. Any publications or supplementary material may be attached. It is expected that the student will meet at least annually with the committee to update the members on his or her progress.

Dissertation Defense: This is the final PhD examination. Upon completion of the dissertation research project, the candidate writes a dissertation that must be successfully defended in an oral examination and public presentation conducted by the doctoral committee. A complete copy of the student’s dissertation must be submitted to each member of the doctoral committee two weeks before the defense. It is understood that this copy of the dissertation given to committee members will not be the final copy, and that the committee members may request changes in the text at the time of the defense. This examination may not be conducted earlier than three quarters after the date of advancement to doctoral candidacy. Acceptance of the dissertation by the Graduate Division and the university librarian represents the final step in completion of all requirements for the doctoral degree.

Teaching Experience: Prior to the dissertation defense, the candidate must serve at least one quarter as a teaching assistant with the responsibility to hold a problem-solving section one hour a week.

Annual Evaluation: In the spring of each year, the faculty adviser evaluates each doctoral student’s overall performance in course work, research, and prospects for financial support for future years. A written assessment is given to the student after the evaluation. If a student’s work is found to be inadequate, the faculty may determine that the student cannot continue in the graduate department.

PhD in Chemical Engineering with Specialization in Multi-scale Biology
A PhD specialization in multi-scale biology, spanning four schools—Jacobs School of Engineering, Health Sciences, Biological Sciences, and Physical Sciences, is available to doctoral candidates in chemical engineering. The PhD specialization is designed to allow students to obtain standard basic training in their chosen field, along with training in integrative and quantitative analysis across multiple scales of biological organization from molecule to organism to health and disease. It educates a new cadre of PhD scientists to undertake interdisciplinary work at the interfaces between the biological, medical, physical, and engineering sciences.