Between April and July 2024, Microsoft observed Iranian state-sponsored threat actor Peach Sandstorm deploying a new custom multi-stage backdoor, which we named Tickler. Tickler has been used in attacks against targets in the satellite, communications equipment, oil and gas, as well as federal and state government sectors in the United States and the United Arab Emirates. This activity is consistent with the threat actor’s persistent intelligence gathering objectives and represents the latest evolution of their long-standing cyber operations.
Peach Sandstorm also continued conducting password spray attacks against the educational sector for infrastructure procurement and against the satellite, government, and defense sectors as primary targets for intelligence collection. In addition, Microsoft observed intelligence gathering and possible social engineering targeting organizations within the higher education, satellite, and defense sectors via the professional networking platform LinkedIn.
Microsoft assesses that Peach Sandstorm operates on behalf of the Iranian Islamic Revolutionary Guard Corps (IRGC) based on the group’s victimology and operational focus. Microsoft further assesses that Peach Sandstorm’s operations are designed to facilitate intelligence collection in support of Iranian state interests.
Microsoft tracks Peach Sandstorm campaigns and directly notifies customers who we observe have been targeted or compromised, providing them with the necessary information to help secure their environment. As part of our continuous monitoring, analysis, and reporting on the threat landscape, we are sharing our research on Peach Sandstorm’s use of Tickler to raise awareness of this threat actor’s evolving tradecraft and to educate organizations on how to harden their attack surfaces against this and similar activity. Microsoft published information on unrelated election interference linked to Iran in the most recent Microsoft Threat Analysis Center (MTAC) report.
In past campaigns, Peach Sandstorm has been observed to use password spray attacks to gain access to targets of interest with a high level of success. The threat actor has also conducted intelligence gathering via LinkedIn, researching organizations and individuals employed in the higher education, satellite, and defense sectors.
During the group’s latest operations, Microsoft observed new tactics, techniques, and procedures (TTPs) following initial access via password spray attacks or social engineering. Between April and July 2024, Peach Sandstorm deployed a new custom multi-stage backdoor, Tickler, and leveraged Azure infrastructure hosted in fraudulent, attacker-controlled Azure subscriptions for command-and-control (C2). Microsoft continuously monitors Azure, along with all Microsoft products and services, to ensure compliance with our terms of service. Microsoft has notified affected organizations and disrupted the fraudulent Azure infrastructure and accounts associated with this activity.
Going back to at least November 2021 and continuing through mid-2024, Microsoft observed Peach Sandstorm using multiple LinkedIn profiles masquerading as students, developers, and talent acquisition managers based in the US and Western Europe. Peach Sandstorm primarily used them to conduct intelligence gathering and possible social engineering against the higher education, satellite sectors, and related industries. The identified LinkedIn accounts were subsequently taken down. Information on LinkedIn’s policies and actions against inauthentic behavior on its platform is available here.
Since at least February 2023, Microsoft has observed Peach Sandstorm carrying out password spray activity against thousands of organizations. In password spray attacks, threat actors attempt to authenticate to many different accounts using a single password or a list of commonly used passwords. In contrast to brute force attacks, which target a single account using many passwords, password spray attacks help adversaries maximize their chances for success and minimize the likelihood of automatic account lockouts.
Microsoft has observed that once Peach Sandstorm has verified a target account’s credentials using the password spray technique, the threat actor performed subsequent sign-ins to the compromised accounts from commercial VPN infrastructure.
In April and May 2024, Microsoft observed Peach Sandstorm conducting password spray attacks targeting organizations in the defense, space, education, and government sectors in the US and Australia. In particular, Peach Sandstorm continued to use the “go-http-client” user agent that they are known to leverage in password spray campaigns. While the password spray activity appeared consistently across sectors, Microsoft observed Peach Sandstorm exclusively leveraging compromised user accounts in the education sector to procure operational infrastructure. In these cases, the threat actor accessed existing Azure subscriptions or created one using the compromised account to host their infrastructure. The attacker-controlled Azure infrastructure then served as C2 or operational hops for Peach Sandstorm operations targeting the government, defense, and space sectors. Recent updates to security defaults in Azure, such as multi-factor authentication help ensure that Azure accounts are more resistant to account compromise techniques such as those used by Peach Sandstorm.
Microsoft Threat Intelligence identified two samples of the Tickler malware, a custom multi-stage backdoor, that Peach Sandstorm deployed in compromised environments as recently as July 2024. The first sample was contained in an archive file named Network Security.zip alongside benign PDF files used as decoy documents. The archive file contained:
YAHSAT NETWORK_INFRASTRUCTURE_SECURITY_GUIDE_20240421.pdf.exe is a 64-bit C/C++ based native PE file. The sample begins with a Process Environment Block (PEB) traversal to locate the in-memory address of file kernell32.dll.
Upon successful PEB traversal yielding the address of kernell32.dll in memory, the sample decrypts a string to LoadLibraryA and resolves its address, decrypts the string “kernel32.dll”, and loads it again using LoadLibraryA. The sample then launches the benign PDF file YAHSAT NETWORK_INFRASTRUCTURE_SECURITY_GUIDE_20240421.pdf as a decoy document.
The sample collects the network information from the host and sends it to the C2 URI via HTTP POST request, likely as a means for the threat actor to orient themselves on the compromised network. The below network information is an example generated in a lab environment:
We subsequently observed Peach Sandstorm iterating and improving on this initial sample. The second Tickler sample, sold.dll, is a Trojan dropper functionally identical to the previously identified sample. The malware downloads additional payloads from the C2 server, including a backdoor, a batch script to set persistence for this backdoor, and the following legitimate files:
The files msvcp140.dll, LoggingPlatform.dll, vcruntime140.dll, and Microsoft.SharePoint.NativeMessaging.exe are legitimate Windows signed binaries likely used for DLL sideloading.
Additionally, we observed the sample downloading the following malicious files:
The batch script adds a registry Run key for a file called SharePoint.exe, likely used to load the malicious DLL files above, thus setting up persistence:
The two DLL files are both 64-bit C/C++ compiled PE DLL files and appear to be functionally identical to the previously analyzed samples. As fully functional backdoors, they can run the following commands:
Microsoft observed Peach Sandstorm creating Azure tenants using Microsoft Outlook email accounts and creating Azure for Students subscriptions in these tenants. Additionally, the group leveraged compromised user accounts in the Azure tenants of organizations in the education sector to do the same. Within these subscriptions, Peach Sandstorm subsequently created Azure resources for use as C2 for the backdoor. Of note, we have observed multiple Iranian groups, including Smoke Sandstorm, use similar techniques in recent months. The following resources were created by Peach Sandstorm for use as Tickler C2 nodes:
In the past year, Peach Sandstorm has successfully compromised several organizations, primarily in the aforementioned sectors, using bespoke tooling. Once Peach Sandstorm gains access to an organization, the threat actor is known to perform lateral movement and actions on objectives using the following techniques:
After compromising a European defense organization, Peach Sandstorm threat actors moved laterally via SMB. SMB lateral movement is a technique used by threat actors to move from one compromised machine to another within a network by exploiting the SMB protocol. This protocol, which is used for sharing files, printers, and other resources on a network, could be misused by attackers to propagate their access and gain control over multiple systems.
In an older intrusion against a multinational pharmaceutical company not associated with the campaign discussed in this blog, after a likely successful password spray attack, Peach Sandstorm attempted to download and install AnyDesk, a commercial RMM tool. AnyDesk has a range of capabilities that allow users to remotely access a network, persist in a compromised environment, and enable command and control. The convenience and utility of a tool like AnyDesk is amplified by the fact that it might be permitted by application controls in environments where it is used legitimately by IT support personnel or system administrators.
In at least one intrusion against a Middle East-based satellite operator, Peach Sandstorm actors compromised a user using a malicious ZIP file delivered via Microsoft Teams message followed by dropping AD Explorer and taking an AD snapshot. An AD snapshot is a read-only, point-in-time copy of the AD database and related files, which can be used for various legitimate administrative tasks. These snapshots can also be exploited by threat actors for malicious purposes.
To harden networks against Peach Sandstorm activity, defenders can implement the following:
To protect against password spray attacks, implement the following mitigations:
Strengthen endpoints against attacks by following these steps:
Microsoft Defender Antivirus detects components of this threat as the following malware:
The following Microsoft Defender for Endpoint alerts can indicate associated threat activity:
The following alerts might also indicate threat activity related to this threat. Note, however, that these alerts can be also triggered by unrelated threat activity.
The following Microsoft Defender for Identity alerts can indicate activity related to this threat. Note, however, that these alerts can be also triggered by unrelated threat activity.
The following Microsoft Defender for Cloud Apps alerts can indicate activity related to this threat. Note, however, that these alerts can be also triggered by unrelated threat activity.
Microsoft Defender Threat Intelligence customers can use the following reports in Microsoft products to get the most up-to-date information about the threat actor, malicious activity, and techniques discussed in this blog. These reports provide the intelligence, protection information, and recommended actions to help prevent, mitigate, or respond to associated threats found in customer environments.
Microsoft Defender XDR customers can run the following query to find related activity in their networks:
The following query identifies failed attempts to sign-in from multiple sources that originate from a single ISP. Attackers distribute attacks from multiple IP addresses across a single service provider to evade detection. Run query
IdentityLogonEvents
| where Timestamp > ago(4h)
| where ActionType == "LogonFailed"
| where isnotempty(AccountObjectId)
| summarize TargetCount = dcount(AccountObjectId), TargetCountry = dcount(Location), TargetIPAddress = dcount(IPAddress) by ISP
| where TargetCount >= 100
| where TargetCountry >= 5
| where TargetIPAddress >= 25
The following queries identifies connectivity to Peach Sandstorm created Azure App Service apps for command and control. Run query
let domainList = dynamic(["subreviews.azurewebsites.net",
"satellite2.azurewebsites.net",
"nodetestservers.azurewebsites.net",
"satellitegardens.azurewebsites.net",
"softwareservicesupport.azurewebsites.net",
"getservicessuports.azurewebsites.net",
"getservicessupports.azurewebsites.net",
"getsupportsservices.azurewebsites.net",
"satellitespecialists.azurewebsites.net",
"satservicesdev.azurewebsites.net",
"servicessupports.azurewebsites.net",
"websupportprotection.azurewebsites.net ",
"supportsoftwarecenter.azurewebsites.net",
"centersoftwaresupports.azurewebsites.net"
"softwareservicesupports.azurewebsites.net",
"getsdervicessupoortss.azurewebsites.net"]);union
(
DnsEvents
| where QueryType has_any(domainList) or Name has_any(domainList)
| project TimeGenerated, Domain = QueryType, SourceTable = "DnsEvents"
),
(
IdentityQueryEvents
| where QueryTarget has_any(domainList)
| project Timestamp, Domain = QueryTarget, SourceTable = "IdentityQueryEvents"
),
(
DeviceNetworkEvents
| where RemoteUrl has_any(domainList)
| project Timestamp, Domain = RemoteUrl, SourceTable = "DeviceNetworkEvents"
),
(
DeviceNetworkInfo
| extend DnsAddresses = parse_json(DnsAddresses), ConnectedNetworks = parse_json(ConnectedNetworks)
| mv-expand DnsAddresses, ConnectedNetworks
| where DnsAddresses has_any(domainList) or ConnectedNetworks.Name has_any(domainList)
| project Timestamp, Domain = coalesce(DnsAddresses, ConnectedNetworks.Name), SourceTable = "DeviceNetworkInfo"
),
(
VMConnection
| extend RemoteDnsQuestions = parse_json(RemoteDnsQuestions), RemoteDnsCanonicalNames = parse_json(RemoteDnsCanonicalNames)
| mv-expand RemoteDnsQuestions, RemoteDnsCanonicalNames
| where RemoteDnsQuestions has_any(domainList) or RemoteDnsCanonicalNames has_any(domainList)
| project TimeGenerated, Domain = coalesce(RemoteDnsQuestions, RemoteDnsCanonicalNames), SourceTable = "VMConnection"
),
(
W3CIISLog
| where csHost has_any(domainList) or csReferer has_any(domainList)
| project TimeGenerated, Domain = coalesce(csHost, csReferer), SourceTable = "W3CIISLog"
),
(
EmailUrlInfo
| where UrlDomain has_any(domainList)
| project Timestamp, Domain = UrlDomain, SourceTable = "EmailUrlInfo"
),
(
UrlClickEvents
| where Url has_any(domainList)
| project Timestamp, Domain = Url, SourceTable = "UrlClickEvents"
)
| order by TimeGenerated desc
The following query will surface events involving malicious files related to this activity. Run query
let fileHashes = dynamic(["711d3deccc22f5acfd3a41b8c8defb111db0f2b474febdc7f20a468f67db0350", "fb70ff49411ce04951895977acfc06fa468e4aa504676dedeb40ba5cea76f37f", "5df4269998ed79fbc997766303759768ce89ff1412550b35ff32e85db3c1f57b", "ccb617cc7418a3b22179e00d21db26754666979b4c4f34c7fda8c0082d08cec4", "7eb2e9e8cd450fc353323fd2e8b84fbbdfe061a8441fd71750250752c577d198"]);
union
(
DeviceFileEvents
| where SHA256 in (fileHashes)
| project Timestamp, FileHash = SHA256, SourceTable = "DeviceFileEvents"
),
(
DeviceEvents
| where SHA256 in (fileHashes)
| project Timestamp, FileHash = SHA256, SourceTable = "DeviceEvents"
),
(
DeviceImageLoadEvents
| where SHA256 in (fileHashes)
| project Timestamp, FileHash = SHA256, SourceTable = "DeviceImageLoadEvents"
),
(
DeviceProcessEvents
| where SHA256 in (fileHashes)
| project Timestamp, FileHash = SHA256, SourceTable = "DeviceProcessEvents"
)
| order by Timestamp desc
Microsoft Sentinel customers can use the TI Mapping analytics (a series of analytics all prefixed with ‘TI map’) to automatically match the malicious domain indicators mentioned in this blog post with data in their workspace. If the TI Map analytics are not currently deployed, customers can install the Threat Intelligence solution from the Microsoft Sentinel Content Hub to have the analytics rule deployed in their Sentinel workspace.
For the latest security research from the Microsoft Threat Intelligence community, check out the Microsoft Threat Intelligence Blog: https://aka.ms/threatintelblog.
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The post Peach Sandstorm deploys new custom Tickler malware in long-running intelligence gathering operations appeared first on Microsoft Security Blog.
Source: Microsoft Security