Not so simple. ProcessType is most likley a knowledge layer object - it defines a certain process. Process on the other hand is an instance of a process that is ProcessType. You probably really don't need or want the bidirectional relationship. Process is probably not a logical child of a ProcessType. They typically belong to something else, like a Product, or Factory or Sequence.
Also by definition when you delete an aggregate root you delete all members of the aggregate. When you delete a Process I seriously doubt you really want to delete ProcessType. If you deleted ProcessType you might want to delete all Processes of that type, but that relationship is already not ideal and chances are you will not be deleting definition objects ever as soon as you have a historical Process that is defined by ProcessType.
I would remove the Processes collection from ProcessType and find a more suitable parent if one exists. I would keep the ProcessType as a member of Process since it probably defines Process. Operational layer (Process) and Knowledge Layer(ProcessType) objects rarely work as a single aggregate so I would have either Process be an aggregate root or possibly find an aggregate root that is a parent for process. Then ProcessType would be a external class. Process.Type is most likely redundant since you already have Process.ProcessType. Just get rid of that.
I have a similar model for healthcare. There is Procedure (Operational layer) and ProcedureType (knowledge layer). ProcedureType is a standalone class. Procedure is a child of a third object Encounter. Encounter is the aggregate root for Procedure. Procedure has a reference to ProcedureType but it is one way. ProcedureType is a definition object it does not contain a Procedures collection.
EDIT (because comments are so limited)
One thing to keep in mind through all of this. Many are DDD purists and adamant about rules. However if you read Evans carefully he constantly raises the possibility that tradeoffs are often required. He also goes to pretty great lengths to characterize logical and carefully thought out design decisions versus things like teams that do not understand the objectives or circumvent things like aggregates for the sake of convenience.
The important things is to understand and apply the concepts as opposed to the rules. I see many DDD that shoehorn an application into illogical and confusing aggregates etc for no other reason than because a literal rule about repositories or traversal is being applied, That is not the intent of DDD but it is often the product of the overly dogmatic approach many take.
So what are the key concepts here:
Aggregates provide a means to make a complex system more manageable by reducing the behaviors of many objects into higher level behaviors of the key players.
Aggregates provide a means to ensure that objects are created in a logical and always valid condition that also preserves a logical unit of work across updates and deletes.
Let's consider the last point. In many conventional applications someone creates a set of objects that are not fully populated because they only need to update or use a few properties. The next developer comes along and he needs these objects too, and someone has already made a set somewhere in the neighborhood fora different purpose. Now this developer decides to just use those, but he then discovers they don't have all the properties he needs. So he adds another query and fills out a few more properties. Eventually because the team does not adhere to OOP because they take the common attitude that OOP is "inefficient and impractical for the real world and causes performance issues such as creating full objects to update a single property". What they end up with is an application full of embedded SQL code and objects that essentially randomly materialize anywhere. Even worse these objects are bastardized invalid proxies. A Process appears to be a Process but it is not, it is partially populated in different ways any given point depending on what was needed. You end up with a ball mud of numerous queries to continuously partially populate objects to varying degrees and often a lot of extraneous crap like null checks that should not exist but are required because the object is never truly valid etc.
Aggregate rules prevent this by ensuring objects are created only at certain logical points and always with a full set of valid relationships and conditions. So now that we fully understand exactly what aggregate rules are for and what they protect us from, we also want to understand that we also do not want to misuse these rules and create strange aggregates that do not reflect what our application is really about simply because these aggregate rules exists and must be followed at all times.
So when Evans says create Repositories only for aggregates he is saying create aggregates in a valid state and keep them that way instead of bypassing the aggregate for internal objects directly. You have a Process as a root aggregate so you create a repository. ProcessType is not part of that aggregate. What do you do? Well if an object is by itself and it is an entity, it is an aggregate of 1. You create a repository for it.
Now the purist will come along and say you should not have that repository because ProcessType is a value object, not an entity. Therefore ProcessType is not an aggregate at all, and therefore you do not create a repository for it. So what do you do? What you don't do is shoehorn ProcessType into some kind of artificial model for no other reason than you need to get it so you need a repository but to have a repository you have to have an entity as an aggregate root. What you do is carefully consider the concepts. If someone tells you that repository is wrong, but you know that you need it and whatever they may say it is, your repository system is valid and preserves the key concepts, you keep the repository as is instead of warping your model to satisfy dogma.
Now in this case assuming I am correct about what ProcessType is, as the other commentor noted it is in fact a Value Object. You say it cannot be a Value Object. That could be for several reasons. Maybe you say that because you use NHibernate for example, but the NHibernate model for implementing value objects in the same table as another object does not work. So your ProcessType requires an identity column and field. Often because of database considerations the only practical implementation is to have value objects with ids in their own table. Or maybe you say that because each Process points to a single ProcessType by reference.
It does not matter. It is a value Object because of the concept. If you have 10 Process objects that are of the same ProcessType you have 10 Process.ProcessType members and values. Whether each Process.ProcessType points to a single reference, or each got a copy, they should still by definition all be exactly the same things and all be completely interchangeable with any of the other 10. THAT is what makes it a value Object. The person who says "It has an Id therefore is cannot be a value Object you have an entity" is making a dogmatic error. Don't make the same error, if you need an ID field give it one, but don't say "it can't be a Value Object" when it in fact is albeit one that for other reason you had to give an Id to.
So how do you get this one right and wrong? ProcessType is a Value Object, but for some reason you need it to have an Id. The Id per se does not violate the rules. You get it right by having 10 processes that all have a ProcessType that is exactly the same. Maybe each has a local deeep copy, maybe they all point to one object. but each is identical either way, ergo each has an Id = 2, for example. You get is wrong when you do this: 10 Processes each have a ProcessType, and this ProcessType is identical and completely interchangeable EXCEPT now each also has it's own unique Id as well. Now you have 10 instances of the same thing but they vary only in Id, and will always vary only in Id. Now you no longer have a Value Object, not because you gave it an Id, but because you gave it an Id with an implementation that reflects the nature of an entity - each instance is unique and different