Algebraic geometry is a very complicated area of mathematics that uses methods from both abstract algebra and geometry to look for answers to sets of polynomial equations. It can be used in many fields, such as robotics, number theory, cryptography, and string theory.
As an algebraic geometer looking to ace your next job interview, you can expect to face a range of technical and conceptual questions that will thoroughly test your grasp over the fundamental concepts as well as the subtle nuances of this fascinating subject.
In this comprehensive guide I will share some of the most common algebraic geometry interview questions along with detailed explanations and tips to help you prepare effectively. Whether you are a student gearing up for an academic interview or a seasoned professional these insights will prove invaluable in showcasing your expertise and landing your dream role.
Why Algebraic Geometry?
Interviewers usually start by asking you about your motivation and how well you understand how algebraic geometry fits into the bigger picture. Some questions to expect:
- What attracted you to the field of algebraic geometry?
- How is algebraic geometry applied in the real world?
- What do you find most exciting or beautiful about this subject?
When answering these demonstrate your passion and highlight some key applications like
- Developing unbreakable cryptographic systems
- Designing robots that can move safely by planning optimal configurations
- Understanding string theory models in theoretical physics
Convey your appreciation for the field’s elegance and how it reveals deep connections between geometry and algebra.
Core Concepts and Definitions
Being well-versed in the fundamental terminology and concepts is vital. Interviewers may ask you to define and explain terms like:
- Scheme
- Variety
- Morphism
- Irreducible components
- Dimension
- Regular and singular points
When responding, provide succinct and technically accurate definitions using relevant examples. Also discuss intuitions behind the concepts and how they generalize familiar objects like affine varieties.
You can expect abstract questions testing whether you grasp the bigger picture, like:
- How are schemes more general than varieties?
- What is the importance of regular rings and points in algebraic geometry?
Key Theorems and Proofs
Given algebraic geometry’s theoretical nature, interviewers will likely probe your in-depth understanding of pivotal theorems like:
- Hilbert Nullstellensatz
- Hilbert Syzygy Theorem
- Bezout’s Theorem
- Riemann-Roch Theorem
Be prepared to concisely state these theorems and their significance. Know relevant definitions involved and key ideas or techniques in proofs. If asked to reproduce a proof, focus on communicating the critical steps and logic flow.
Also expect conceptual questions that build on theorems, for example:
- How does the Nullstellensatz help count solutions of polynomial systems?
- In what way does the Riemann-Roch theorem generalize the dimension formula for affine space?
Problem-solving Techniques
The real test of your algebraic geometry skills will be tackling problems. Interview questions may involve:
- Computing dimensions, degrees and genera of varieties
- Determining irreducibility or singularity of specific varieties
- Proving isomorphisms between curves or surfaces
- Finding rational points on curves over number fields
- Handling intersections, products and projections of varieties
When attempting these, clearly explain your reasoning while applying suitable techniques like:
- Leveraging Bézout’s theorem
- Using dimension formulas
- Applying Riemann-Hurwitz formula
- Handling Zariski tangent spaces
Also highlight relevant intuitions guiding your approach. Don’t get bogged down in messy calculations – first outline the strategy.
Connections with Related Areas
Demonstrate how you view algebraic geometry in a broader mathematical context via questions like:
- How are algebraic geometry and number theory linked?
- What key tools from commutative algebra are used in algebraic geometry?
- What parallels exist between algebraic geometry and differential geometry?
Emphasize cross-cutting ideas like utilizing valuation theory to extend variety notions to non-algebraically closed fields. Discuss algebraic techniques like localization and how geometric objects analogously behave upon restricting to open sets.
Keeping Current
It is crucial to show you actively engage with the research community. Be ready for questions like:
- Which recent advances in algebraic geometry interest you?
- What journals, conferences or seminars help you stay up-to-date?
- Who are some leading researchers in your sub-field presently?
Mention specific new techniques (e.g. perfectoid spaces) and how they address challenges in the field. Highlight major events like the algebraic geometry conference series or forums like MathOverflow to exhibit your participation.
Teaching and Communication
Interviewers will assess your ability to explain intricate concepts simply and clearly. Some questions to expect are:
- How would you describe algebraic geometry and its significance to a high school student?
- What is an accessible analogy to help newcomers intuit the idea of varieties?
- What are effective visuals to represent abstract notions like tangent spaces?
Respond with relatable explanations and examples pitching ideas at an appropriate level for the audience. Emphasize geometric intuitions and connections to familiar concepts when possible. This showcases your passion for the subject and teaching skills.
Looking Ahead
Finally, expect questions probing your future research aims and interests like:
- What open problems intrigue you in algebraic geometry?
- Are there adjacent areas you wish to explore further?
- What do you envision as exciting new directions in this field?
Convey ambitious yet realistic goals aligned with your expertise like tackling conjectures in moduli spaces or algebraic cycles. Discuss expanding into pertinent domains like tropical geometry, as well as dreams like unlocking connections to physics. This provides interviewers insight into your vision and potential.
Preparing thoroughly for algebraic geometry interviews takes time and dedication. But mastering core concepts, theorems and problem-solving approaches will give you the confidence to tackle any question. Along with highlighting your motivation and vision, you can show interviewers your readiness to take on new challenges and thrive in the role.
So tackle those practice problems, internalize major results in the field, and articulate your passion for this fascinating subject. With diligent preparation and the insights above, you will be primed to conquer your upcoming interviews!
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12 Answers 12 Sorted by:
Perhaps youre going about this the wrong way. If you want to explain what most algebraic geometers do today, try to explain a problem or set of problems that are pretty clear and easy to understand. I think there are plenty of topics to choose from. Youve already mentioned solving systems of equations. Some algebraic geometers don’t even try to find solutions; they just want to know when there are solutions (Nullstellensatz) and how many parameters are needed. Another important reason in history is the study of elliptic and abelian integrals: you can go from adding laws for integrals to adding laws on curves (Jacobian).
Abhyankars book Algebraic Geometry for Scientists and Engineers doesnt give a short answer, but many long ones, with explicit examples of determining the geometric nature of the solutions of algebraic equations.
In conversations like this, I usually lead with a concrete example of a hard problem. One way to check this is to notice that two surfaces in three-space usually meet in a curve. Then, ask yourself if, given an algebraically defined curve, it is always the intersection of two algebraically defined surfaces. How do you tell the difference between those that are and those that aren’t? This gives you a chance to talk about how important it is to use both geometric intuition and algebraic calculations.
Now generalize to higher dimensions. Now, if they still want more, you can get into more specifics, like the difference between a real complete intersection and a set-theoretic complete intersection. Or give a sequence of increasingly challenging specific cases. Et cetera.
Ive also — though this is sort of cheating — used the example of classifying vector bundles. In the case of topology, this is easy to explain: let’s say you have a circle and you want to connect a line to every point on the circle in a straight line. You can make a cylinder, or you can make a Mobius strip. Do you know when two of these things are “the same”? What else can you make? Keep in mind that the answers to these questions depend on the rules you set for how you’ll build your objects and when you think two of them are “the same.” If you want to study topology, everything has to be continuous. If you want to study algebraic geometry, everything has to be continuous. It’s pretty easy to see that all vector bundles of a certain rank are topologically equivalent if the base space is also a vector space. But it’s not so easy to see this in the algebraic case. Et cetera.
This is along the lines suggested by @DonuArapura: “describe a problem [. ] that is reasonably concrete and accessible, and go from there. “.
An engineer would enjoy this puzzle: what kinds of bent wire can go through a pinhole in a plane without moving at all? These kinds of curves are called threadable curves. 1.
Deciding whether a given planar algebraic curve $C$ is threadable depends on the number of bitangents. For a curve of degree $d$, this number is $O(d^4)$, a result of Schubert. See the MO question, Number of bitangents to connected algebraic curve.
1J.ORourke and Emmely Rogers, “Threadable curves,” Proc. 30th Canad. Conf. Comput. Geom., Aug 2018, 328—333. (arXiv abstract).
If you only want to explain what algebraic geometry is and not try to persuade the engineer that it’s important to study, a good place to start is to talk about the different types of conic sections (ellipse, parabola, and hyperbola) and how algebraic geometers try to group the different outcomes that can happen when there are more degrees, equations, or variables.
Another “disconnect” between engineers and mathematicians is that they don’t understand PDEs the same way you do. Engineers often just want to solve PDEs. Mathematicians are interested in solving PDEs too but are also interested in other questions. It might be easier to explain the idea of wanting to understand the qualitative features of a solution in terms of PDEs. Then you can say that the situation in algebraic geometry is similar.
I have had this conversation a few times. I start by explaining the idea of abstract classification of objects. I show them how a mechanical arm that can turn in a circle and has another mechanical arm at the end that can also turn in a circle is, in a way, the same thing as a torus, even though they look different. That being said, the question is how to group things that are defined by rules that look different but are really the same?
I then explain that in A. G. Most of the time, the constraints are polynomials, which lets you use ideas and points of view that totally general constraints don’t allow.
I believe a good explanation should show how algebraic geometry can help us understand what a general point on an irreducible variety really means.
I could use Gerstenhaber’s Theorem as an example. It says that the number of pairs of commuting complex matrices is uncountable. A generic pair is two commuting diagonalizable matrices with different eigenvalues. I think one could give a good idea of this without (explicitly) using the group action or topology. The engineer might already know that rotations of $mathbb{R}^3$ can be diagonalized over $mathbb{C}$. If that’s the case, I would tell them that these matrices aren’t quite general because of the $1$ eigenvalue.
If they want to know more, I’d say that the variety diminishes as the number of matrices increases, which means there is no good reason to think of a generic tuple.
One of the things engineers are very familiar with is integration. “What kind of substitution should I make to explicitly find antiderivative?” is a very natural question. And, you know, Algebraic Geometry sometimes helps with that.
My favorite answer for this kind of question is to start with an integral of something in $mathbb{R}(sin(t),cos(t))$. To write the point $(sin(t),cos(t))$ in terms of $tan(t/2)$, I then use a unit circle and stereographic projection. This leads to the substitution that solves the antiderivative. And a short explanation of how you discover links between algebraic expressions and geometric objects that help you understand the algebraic object
I would start by showing them to how find rational points on a conic. If you have a rational point then you can draw lines and find more. Once they understand the geometry, you can stress the “rationality” part of the construction: “Look, both the slope and the y-intercept are rational, so if one point of intersection is rational, then the other one is too.”
This building has just the right number of logical steps for the engineer to be able to check them if they want to. g. rationality, getting all of them, the necessity of finding a point to start off the process.
Then you could let them play with a quadratic extension (!) to “see what happens.”
This is a good example because both the algebra and geometry are easy enough for your audience to understand.
That’s as far as I’d go with curves.
There are several good answers already so I cannot hope to add much. Still, another way to get engineers’ attention could be to use the well-known subject of linear algebra, especially the idea that solving systems of linear equations is similar to solving systems of polynomial equations.
Start by quickly going over linear systems and why there must be zero, one, or an infinite number of solutions. Show the usual pictures of lines and planes crossing in $mathbb{R}^2$ and $mathbb{R}^3$, such as two planes crossing in a line and a plane and a line crossing in a point. For example, you could use this to start a conversation about the size of solution sets for polynomial equations, the Hilbert Nullstellensatz, and Bezout’s Theorem.
I would say that it’s a subject where you do geometry and think about geometry, but you write about it in a way that sounds like algebra and use algebra, which can be pretty hard to understand. Here is an example from Weibel’s Introduction to Homological Algebra (page 119). Hartshorne first used this idea.
Let $R = mathbb{C}[x_1, x_2, y_1, y_2]$, $P=(x_1,x_2)R$, $Q=(y_1,y_2)R$, and $I = P : cap : Q $.
Regular sequences make up $P$, $Q$, and $m = P Q = (x_1, x_2, y_1, y_2)R$. This means that the outside terms in the Mayer-Vietoris sequence are also regular sequences.
$H^3_P(R) bigoplus H^3_Q (R) rightarrow H_I^3(R) rightarrow H^4_m(R) rightarrow H^4_P(R) bigoplus H^4_Q (R) $
vanish, which tells us that $H^3_I(R) simeq H^4_m(R) eq 0$. (The cohomology is local cohomology here).
A normal engineer might find this hard to understand, but if you take away the words and jargon, it means that the union of two planes in $mathbb{C}^4$ that meet at a point can’t be described as the solutions of only two equations $f_1 = f_2 =0$. This is a real geometric fact.
There is an answer by D. Mumford to biologists, valid also for engineers: Can one explain schemes to biologists, blog post (2014) (link).
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